- Email: [email protected]
Sequences of two cDNA clones from the medfly Ceratitis capitata encoding antibacterial peptides of the cecropin family
Gene, 134 (1993) 241-243 0 1993 Elsevier Science Publishers
B.V. All rights reserved.
241
0378-t 119/93/$06.00
GENE 07348
Sequences of two cDNA clones from the medfly Ceratitis capitata encoding antibacterial peptides of the cecropin family* (Insect immunity; ceratotoxin; sarcotoxin; homology; medfly cDNA library)
magainin;
Marco Rosettoa, Andrea G.O. Manetti”, Cosima T. Baldari” aDepcwtmrnt
ofEvolutionaryBiology,
Received by G. Bernardi:
18 January
53100 Sienu, Ituly;
recombinant
Daniela
and bl.R.I.S.,
1993; Revised/Accepted:
DNA; nucleotide
Marchini”,
Via Fiorrntina
3 May/l0
sequence;
Roman0
amino
acid sequence
Dallai”, John L. Telfordb and
I. 53100 Siena, Itdy.
May 1993; Received at publishers:
Tel. (39-577)
293470
17 June 1993
SUMMARY
Using a backtranslated oligodeoxyribonucleotide probe, encoding a conserved we have isolated two cDNA clones from the medfly, Ceratitis capituta. Sequence encode two closely related peptides which are members of the cecropin family.
INTRODUCTION
Antimicrobial peptides have been isolated from both invertebrates and vertebrates. They include, among others, the cecropins (Ccc) and the diptericins from insects (reviewed in Boman and Hultmark, 1987; Hoffmann and Hoffmann, 1990), the magainins from amphibians (Zasloff, 1987) and the defensins from mammalian polymorphonuclear lymphocytes (Selsted et al., 1985). Although different in primary structure, many of these peptides can form amphipathic a-helices and kill bacteria by attacking the cell membrane, probably through the formation of ion channels (Okada and Natori, 1985a; Wade et al., 1990). Most antibacterial peptides are produced in insects in response to infection. Among the most potent of the inDr. C.T. Baldari, Department of Evolutionary Via Mattioli 4, 53100 Sierra, Italy. Tel. (39-577) 293470; Fax 298898.
Corrrspondencr
Biology. (39-577)
to:
*On request. the authors will supply detailed experimental the conclusions reached in this Short Communication.
evidence
for
Abbreviations: aa, amino acids(s); bp. base pair(s); cDNA, DNA complementary to RNA; Ccc, cecropin(s); Ctx, ceratotoxin; kb, kilobase or 1000 bp; nt, nucleotide(s); oligo, ohgodeoxyribonucleotide; ORF, open reading frame; SP. signal peptide(
motif in insect antibacterial peptides, determination shows that the cDNAs
ducible antimicrobial peptides are the Ccc (reviewed in Boman and Hultmark, 1987). Interestingly, the Ccc locus in Drosophila melanogaster has been shown to include the gene encoding andropin, a male-specific antimicrobial peptide which is constitutively produced in the ejaculatory duct (Samakovlis et al., 1991). Recently two closely related antibacterial peptides have also been purified from the female reproductive accessory glands secretion in Ceratitis capitata (Marchini et al., 1993). Here we present the sequence of two cDNA clones from the medfly Ceratitis capitata encoding peptides of the Ccc family.
EXPERIMENTAL
AND DISCUSSION
(a) Cloning and sequence determination of two medfly cDNAs We have screened a hgtll cDNA library from adult females of Ceratitis capitata for the genes coding for the female antibacterial peptides ceratotoxins (Ctx) (Marchini et al., 1993). The oligo which was used in the screening was designed by backtranslation of the middle portion of medfly Ctx A and Ctx B (Marchini et al., 1993) using Drosophila codon bias (see Fig. 1). This region con-
242 A
to the backtranslated M
60 1
Q
T
120 21
AAATCGAACGCGTTGGTCAGCATACCA I E R" G Q H T
R
180 41
GGTTCCCGCGTCTTAAACAGTTTAGGTATAcATccT*TTGT~G~TATcTGTc~
TGAATTTCAACARAGTCTTCATCCTCGTTGCCATCGTCATCGC~TTTTCGCAGGGCN F N K V F I L VA I V I A I F CTGAAGCGGGTTGGCTG~ E A G W L
K
K
I
G
K
K
A
GAGATGCCACGATCCAAACCATCGCTGTGGCCC~C~GCTGCT~TGTCGCAGCCACCG I Q T I A "A Q Q AA NV DA T
A
G
A
T
240 A 61
CCCGGGGTTAAAAACTGAAATTTGCTAGCGAGCTTCATTACC~GATACGAGCATTTCAC R G
300 63
ACAATATTTACTGCCTAATTTATTTAATTTATCAGTATGCGCTTATATTATGTTAAGACTTTTAAAATAAATTCATATTCAAAATT
360 389
B 60
ATTCGAACGTCACAGCAAATAGCAGCCTTCGCAACTGCAGTACAC GAATAACACAAAGARATAAACATTCGAAATGAATTTCAAGTATTGGTTCTCCTC FNKVLVLL M N
120 10
GCTGTCATCTTTGCCGTTTTCGCTGGACRAACCGAGGCAGGCAGGTTGGCTG~ATTGGC AVIFAVFAGQTEAGWLKKIG
180 30
BBG&4AATTGAGCGCGTCGGCCAACATACATACACGAGATGCCAC~TCCAGACCATCGGTGTG K K I ERVGQHTRDATIQTIG"
240 50
GCCCAACAGGCTGCCAATGTTGCTGCAACGCTGRGGGATAAACTTGTTGTTTTATTTATATT AQQAANVAATLKG
300 63
AGCTGATAAACTATAAATGTAAATGTAGATTAAGTGATT~TTTATTTATTTCAGCTGTT TGATATTAAAGCAAAACTTTTGCACGAAAATT
360 392
Fig. 1. Nucleotide sequences of two Ccc cDNA clones, Cccl (A) and Cec2 (B), from the medfly Cerafitis capirutu. The deduced aa sequence of the ORFs is shown below the nt sequence. The oligo used for the screening was the 30-mer 5’-CCGGTGGCCAAGAAGATTGGCAAGATTGCC encoding the lo-aa peptide PVAKKIGKIA. The nt sequence was determined using the Sequenase kit from US Biochemical (Cleveland, OH, USA). The underlined regions show the homology with the oligo. The nt sequences will appear in the EMBL and GenBank nt sequence X70029 (B).
databases
with
accession
numbers
X70030
(A)
and
tains the Lys-rich motif KKIGK present as such (KKIGK) or with one substitution in other antibacterial peptides, namely Ccc A (KKIEK; Steiner et al., 1981) and B (KKIEK; von Hofsten et al., 1985) from Hyalophora cecropia, Ccc B from Antherea (KKIEK; Craig et al., 1987), Ccc A and Ccc B from Bombyx mori (KKIEK; Teshima et al., 1986), sarcotoxin IA from Sarcophugu peregrinu (KKIGK; Okada and Natori, 1985b), Ccc A from Drosophila melunoguster (KKIGK; Kylsten et al., 1990) and magainin 2 from Xenopus luevis (KKFGK; Zasloff, 1987). Screening of the cDNA library with this oligo, in addition to Ctx cDNA, revealed two other clones which hybridised at low stringency. The nt sequence of the two cDNAs was determined and is presented in Fig. 1A and 1B. The two cDNAs show a high sequence homology, with 75% identity. Their homology
1. 2. 3. 4. 5. 6.
a short sequence
oligo used as a probe is limited
of 16 bp encoding
served in other antibacterial
the aa sequence
to
con-
peptides.
(b) The aa sequence analysis of the ORFs Each cDNA has a single ORF which codes for 63 aa. The conceptual translation products of these two clones revealed 84% aa identity and 98% similarity over most of the sequence
(Fig. 2). The lowest identity
is found be-
tween the N-terminal
16 aa of the two molecules,
this region
cases resembles
in both
closely
secretion signal peptides (SP), with a putative tidase cleavage site after aa 21 (von Heijne,
however eukaryotic
signal pep1986). The
presumptive mature peptides differ by only 3 aa. The two cDNAs are closely related to the members of the melunoguster gene cluster encoding the antibacterial peptides known as Ccc (Kylsten et al., 1990). As shown in Fig. 2, the conceptual translation products of the two cDNAs show a very high aa sequence homology with Drosophilu Ccc (with over 70% identity and about 90% similarity) (Fig. 2). Extensive aa sequence homology can also be found with another dipteran Ccc, sarcotoxin IA from the flesh fly Surcophuga peregrina (Matsumoto et al., 1986). Comparison of medfly and lepidopteran Ccc shows a limited homology (see the extensive aa sequence comparison between dipteran and lepidopteran Ccc precursors recently carried out by Taniai et al. (1992)). In Drosophila, the Ccc are a family of at least four closely related peptides (Tryselius et al., 1992). They are produced as pre-pro peptides which, by analogy to the well characterised Ccc from Hyulophora cecropiu (Boman et al., 1989) are assumed to be processed to yield the mature forms by removal at the N terminus of a SP followed by removal of a pro-sequence by a dipeptidyl aminopeptidase (Kylsten et al., 1990). In addition, as in Hyulophoru and Surcophugu (von Hofsten et al., 1985; Matsumoto et al., 1986), the C-terminal Gly is probably split resulting in amidation of the second last aa. Although there is little aa identity between the putative SP of the medfly cDNA translation products and other dipteran Ccc, the mature peptides are up to 90% identical in aa sequence, including the presumptive dipeptidase cleavage site and the C-terminal Gly (Fig. 2). Ccc are produced in response to bacterial infection and Drosophila
MNFNKVFILVAIVIAIFAGQTEAGWLKKIGKKIERVGQHTRDATIQTIAVAQQ~~TARG G wLIryI%Y XHL YE u TL S GhGI S VhGL LYE 66L EL.Bzz flk I &GI XIYE Id& % s LE I QM1 F LLH Y SQ
63 LK
Fig. 2. Comparison of the aa sequences of medfly Cccl (1) and Cec2 (2) with Drosophila CecA (3). CecB (4). Ccc C (5) and with sarcotoxin IA (6). Only the aa which differ from medfly Cccl primary structure are shown. Similar aa are underlined. Arrowheads show the potential cleavage site of the SP (left arrowhead) and the potential cleavage site by a dipeptidyl aminopeptidase (right arrowhead).
243 injury
(Boman
and Hultmark,
tion has however in Drosophila (Kylsten
1987). Ccc gene transcrip-
been shown to be completely
repressed
only when the flies were grown
axenically
et al., 1990). Northern
used to construct
blot analysis
the medfly cDNA library
of the RNA revealed
only
a very low amount of Ccc-specific mRNA (data not shown). As in Drosophila, this could be accounted for by the possible presence of bacterial contamination in the food. We conclude,
therefore,
that the two cDNAs
in this paper code for medfly homologues
presented
of other insect
Ccc and as such name them Cccl and Cec2.
antibacterial peptides from the female reproductive of the medfly Ceratiris capitata (Insecta, Diptera).
accessory glands Insect Biochem.
Mol. Biol. (1993) in press. Matsumoto,
N., Okada,
M., Takahashi,
H., Ming, Q.X., Nakajima.
Komano, H. and Natori. S.: Molecular assignment of the C-terminal of sarcotoxin protein of Sarcophuga peregrina. Okada, M. and Natori, S.: lonophore
Y.,
cloning of a cDNA and IA, a potent antibacterial
Biochem. J. 239 (1986) 717-722. activity of sarcotoxin I, a bacteri-
cidal of Sarcophagu peregrina. Biochem. J. 260 (1985a)4533458. Okada, M. and Natori, S.: Primary structure of sarcotoxin I, an antibacterial protein induced in hemolymph of Sarcophuga peregrina (flesh fly) larvae. J. Biol. Chem. 260 (1985b) 717447177. Samakovlis, C., Kylsten, P.. Kimbrell. D.A., EngstrBm, A. and Hultmark. D.: The An&pin gene and its product, a male-specific antibacterial peptide in Drosophilu melnnogasrrr. EMBO J. IO (1991) 1633169. Selsted, M.E., Brown, D.M., DeLange, R.G., Harwig, S.S.L. and Lehrer, RI.: Primary structures of six antimicrobial peptides of rabbit peri-
ACKNOWLEDGEMENTS
toneal neutrophils. Steiner, H., H&mark,
Research supported by the Italian National Research Council (CNR), Special Project RAISA, Subproject No. 2, paper No. 1053.
Sequence and specificity of two antibacterial proteins involved in insect immunity. Nature 292 (1981) 2466248. Taniai, K., Kato. Y., Hirochika, H. and Yamakawa. M.: Isolation and
H.G. and H&mark,
H.G.:
nucleotide sequence of cecropin B cDNA clones from the silkworm, Bombyx mori. Biochim. Biophys. Acta 1132 ( 1992) 2033206. Teshima, T., Ueki, Y., Nakai, T., Shiba, T. and Kikuchi, M.: Structure determination of lepidopteran, self-defense substance produced by silkworm. Tetrahedron 42 (1986) 8299834. Tryselius, Y., Samakovlis, C., Kimbrell, D.A. and Hultmak, D.: CecC,
REFERENCES Boman,
J. Biol. Chem. 260 (1985) 457994584. D., Engstrom, A., Bennich, H. and Boman,
D.: Cell-free
Rev. Microbial. 41 (1987) 103-126. Boman, H.G., Boman, LA., Andreu,
immunity
D., Li, Z.-q,
in insects, Annu. Merrifield,
R.B.,
Schlenstedt, G. and Zimmermann, R.: Chemical synthesis and enzymatic processing of precursor forms of cecropins A and B.J. Biol. Chem. 264 (1989) 5852-5860. Craig, A.G.. Engstrom, A., Bennich, H. and Kamensky, I.: Plasma desorption mass spectrometry coupled with sequencing techniques. Biomed. Environ. (1987) 6699673. Hoffmann, J.A. and Hoffmann, D.: The inducible of dipteran insects. Res. Immunol. 141 (1990)
conventional peptide Mass Spectrom. 14 antibacterial 910-918.
peptides
Kylsten, P., Samakovlis, C. and Hultmark, D.: The cecropin locus in Drosophila: a compact gene cluster involved in response to infection. EMBO J. 9 (1990) 2177224. Marchini. D., Giordano, P.C., Amons, R., Bernini, L.F. and Dallai, R.: Purification and primary structure of ceratotoxin A and B, two
a cecropin gene expressed during metamorphosis pupae. Eur. J. Biochem. (1992) 395-399. Van Hofsten,
P., Faye, I., Kockum,
in Drosophila
K., Lee, J.-Y., Xanthopoulos,
KG.,
Boman, I.A., Boman. H.G.. Engstrom, A., Andreu, D. and Merrifield, R.B.: cDNA sequencing, and chemical synthesis of cecropin B from Hvalophora cecropia. Proc. Nat]. Acad. Sci. USA 82 (1985) 2240-2243. von Heijne, G.: A new method sites. Nucleic Acids Res. 14 Wade, D., Boman, A., Wahlin, H.G. and Merrifield, R.B.: forming antibiotic peptides. 4761-4765.
for predicting signal sequence cleavage (1986) 468334690. B., Drain, C.M.. Andreu, D., Boman, All-~ aminoacid-containing channelProc. Nat]. Acad. Sci. USA 87 (1990)
Zasloff, M.: Magainins, a class of antimicrobial peptides from Xenopus skin: isolation, characterization of two active forms, and partial cDNA sequence 544995453.
of a precursor.
Proc. Natl. Acad. Sci. USA 84 (1987)
B.V. All rights reserved.
241
0378-t 119/93/$06.00
GENE 07348
Sequences of two cDNA clones from the medfly Ceratitis capitata encoding antibacterial peptides of the cecropin family* (Insect immunity; ceratotoxin; sarcotoxin; homology; medfly cDNA library)
magainin;
Marco Rosettoa, Andrea G.O. Manetti”, Cosima T. Baldari” aDepcwtmrnt
ofEvolutionaryBiology,
Received by G. Bernardi:
18 January
53100 Sienu, Ituly;
recombinant
Daniela
and bl.R.I.S.,
1993; Revised/Accepted:
DNA; nucleotide
Marchini”,
Via Fiorrntina
3 May/l0
sequence;
Roman0
amino
acid sequence
Dallai”, John L. Telfordb and
I. 53100 Siena, Itdy.
May 1993; Received at publishers:
Tel. (39-577)
293470
17 June 1993
SUMMARY
Using a backtranslated oligodeoxyribonucleotide probe, encoding a conserved we have isolated two cDNA clones from the medfly, Ceratitis capituta. Sequence encode two closely related peptides which are members of the cecropin family.
INTRODUCTION
Antimicrobial peptides have been isolated from both invertebrates and vertebrates. They include, among others, the cecropins (Ccc) and the diptericins from insects (reviewed in Boman and Hultmark, 1987; Hoffmann and Hoffmann, 1990), the magainins from amphibians (Zasloff, 1987) and the defensins from mammalian polymorphonuclear lymphocytes (Selsted et al., 1985). Although different in primary structure, many of these peptides can form amphipathic a-helices and kill bacteria by attacking the cell membrane, probably through the formation of ion channels (Okada and Natori, 1985a; Wade et al., 1990). Most antibacterial peptides are produced in insects in response to infection. Among the most potent of the inDr. C.T. Baldari, Department of Evolutionary Via Mattioli 4, 53100 Sierra, Italy. Tel. (39-577) 293470; Fax 298898.
Corrrspondencr
Biology. (39-577)
to:
*On request. the authors will supply detailed experimental the conclusions reached in this Short Communication.
evidence
for
Abbreviations: aa, amino acids(s); bp. base pair(s); cDNA, DNA complementary to RNA; Ccc, cecropin(s); Ctx, ceratotoxin; kb, kilobase or 1000 bp; nt, nucleotide(s); oligo, ohgodeoxyribonucleotide; ORF, open reading frame; SP. signal peptide(
motif in insect antibacterial peptides, determination shows that the cDNAs
ducible antimicrobial peptides are the Ccc (reviewed in Boman and Hultmark, 1987). Interestingly, the Ccc locus in Drosophila melanogaster has been shown to include the gene encoding andropin, a male-specific antimicrobial peptide which is constitutively produced in the ejaculatory duct (Samakovlis et al., 1991). Recently two closely related antibacterial peptides have also been purified from the female reproductive accessory glands secretion in Ceratitis capitata (Marchini et al., 1993). Here we present the sequence of two cDNA clones from the medfly Ceratitis capitata encoding peptides of the Ccc family.
EXPERIMENTAL
AND DISCUSSION
(a) Cloning and sequence determination of two medfly cDNAs We have screened a hgtll cDNA library from adult females of Ceratitis capitata for the genes coding for the female antibacterial peptides ceratotoxins (Ctx) (Marchini et al., 1993). The oligo which was used in the screening was designed by backtranslation of the middle portion of medfly Ctx A and Ctx B (Marchini et al., 1993) using Drosophila codon bias (see Fig. 1). This region con-
242 A
to the backtranslated M
60 1
Q
T
120 21
AAATCGAACGCGTTGGTCAGCATACCA I E R" G Q H T
R
180 41
GGTTCCCGCGTCTTAAACAGTTTAGGTATAcATccT*TTGT~G~TATcTGTc~
TGAATTTCAACARAGTCTTCATCCTCGTTGCCATCGTCATCGC~TTTTCGCAGGGCN F N K V F I L VA I V I A I F CTGAAGCGGGTTGGCTG~ E A G W L
K
K
I
G
K
K
A
GAGATGCCACGATCCAAACCATCGCTGTGGCCC~C~GCTGCT~TGTCGCAGCCACCG I Q T I A "A Q Q AA NV DA T
A
G
A
T
240 A 61
CCCGGGGTTAAAAACTGAAATTTGCTAGCGAGCTTCATTACC~GATACGAGCATTTCAC R G
300 63
ACAATATTTACTGCCTAATTTATTTAATTTATCAGTATGCGCTTATATTATGTTAAGACTTTTAAAATAAATTCATATTCAAAATT
360 389
B 60
ATTCGAACGTCACAGCAAATAGCAGCCTTCGCAACTGCAGTACAC GAATAACACAAAGARATAAACATTCGAAATGAATTTCAAGTATTGGTTCTCCTC FNKVLVLL M N
120 10
GCTGTCATCTTTGCCGTTTTCGCTGGACRAACCGAGGCAGGCAGGTTGGCTG~ATTGGC AVIFAVFAGQTEAGWLKKIG
180 30
BBG&4AATTGAGCGCGTCGGCCAACATACATACACGAGATGCCAC~TCCAGACCATCGGTGTG K K I ERVGQHTRDATIQTIG"
240 50
GCCCAACAGGCTGCCAATGTTGCTGCAACGCTGRGGGATAAACTTGTTGTTTTATTTATATT AQQAANVAATLKG
300 63
AGCTGATAAACTATAAATGTAAATGTAGATTAAGTGATT~TTTATTTATTTCAGCTGTT TGATATTAAAGCAAAACTTTTGCACGAAAATT
360 392
Fig. 1. Nucleotide sequences of two Ccc cDNA clones, Cccl (A) and Cec2 (B), from the medfly Cerafitis capirutu. The deduced aa sequence of the ORFs is shown below the nt sequence. The oligo used for the screening was the 30-mer 5’-CCGGTGGCCAAGAAGATTGGCAAGATTGCC encoding the lo-aa peptide PVAKKIGKIA. The nt sequence was determined using the Sequenase kit from US Biochemical (Cleveland, OH, USA). The underlined regions show the homology with the oligo. The nt sequences will appear in the EMBL and GenBank nt sequence X70029 (B).
databases
with
accession
numbers
X70030
(A)
and
tains the Lys-rich motif KKIGK present as such (KKIGK) or with one substitution in other antibacterial peptides, namely Ccc A (KKIEK; Steiner et al., 1981) and B (KKIEK; von Hofsten et al., 1985) from Hyalophora cecropia, Ccc B from Antherea (KKIEK; Craig et al., 1987), Ccc A and Ccc B from Bombyx mori (KKIEK; Teshima et al., 1986), sarcotoxin IA from Sarcophugu peregrinu (KKIGK; Okada and Natori, 1985b), Ccc A from Drosophila melunoguster (KKIGK; Kylsten et al., 1990) and magainin 2 from Xenopus luevis (KKFGK; Zasloff, 1987). Screening of the cDNA library with this oligo, in addition to Ctx cDNA, revealed two other clones which hybridised at low stringency. The nt sequence of the two cDNAs was determined and is presented in Fig. 1A and 1B. The two cDNAs show a high sequence homology, with 75% identity. Their homology
1. 2. 3. 4. 5. 6.
a short sequence
oligo used as a probe is limited
of 16 bp encoding
served in other antibacterial
the aa sequence
to
con-
peptides.
(b) The aa sequence analysis of the ORFs Each cDNA has a single ORF which codes for 63 aa. The conceptual translation products of these two clones revealed 84% aa identity and 98% similarity over most of the sequence
(Fig. 2). The lowest identity
is found be-
tween the N-terminal
16 aa of the two molecules,
this region
cases resembles
in both
closely
secretion signal peptides (SP), with a putative tidase cleavage site after aa 21 (von Heijne,
however eukaryotic
signal pep1986). The
presumptive mature peptides differ by only 3 aa. The two cDNAs are closely related to the members of the melunoguster gene cluster encoding the antibacterial peptides known as Ccc (Kylsten et al., 1990). As shown in Fig. 2, the conceptual translation products of the two cDNAs show a very high aa sequence homology with Drosophilu Ccc (with over 70% identity and about 90% similarity) (Fig. 2). Extensive aa sequence homology can also be found with another dipteran Ccc, sarcotoxin IA from the flesh fly Surcophuga peregrina (Matsumoto et al., 1986). Comparison of medfly and lepidopteran Ccc shows a limited homology (see the extensive aa sequence comparison between dipteran and lepidopteran Ccc precursors recently carried out by Taniai et al. (1992)). In Drosophila, the Ccc are a family of at least four closely related peptides (Tryselius et al., 1992). They are produced as pre-pro peptides which, by analogy to the well characterised Ccc from Hyulophora cecropiu (Boman et al., 1989) are assumed to be processed to yield the mature forms by removal at the N terminus of a SP followed by removal of a pro-sequence by a dipeptidyl aminopeptidase (Kylsten et al., 1990). In addition, as in Hyulophoru and Surcophugu (von Hofsten et al., 1985; Matsumoto et al., 1986), the C-terminal Gly is probably split resulting in amidation of the second last aa. Although there is little aa identity between the putative SP of the medfly cDNA translation products and other dipteran Ccc, the mature peptides are up to 90% identical in aa sequence, including the presumptive dipeptidase cleavage site and the C-terminal Gly (Fig. 2). Ccc are produced in response to bacterial infection and Drosophila
MNFNKVFILVAIVIAIFAGQTEAGWLKKIGKKIERVGQHTRDATIQTIAVAQQ~~TARG G wLIryI%Y XHL YE u TL S GhGI S VhGL LYE 66L EL.Bzz flk I &GI XIYE Id& % s LE I QM1 F LLH Y SQ
63 LK
Fig. 2. Comparison of the aa sequences of medfly Cccl (1) and Cec2 (2) with Drosophila CecA (3). CecB (4). Ccc C (5) and with sarcotoxin IA (6). Only the aa which differ from medfly Cccl primary structure are shown. Similar aa are underlined. Arrowheads show the potential cleavage site of the SP (left arrowhead) and the potential cleavage site by a dipeptidyl aminopeptidase (right arrowhead).
243 injury
(Boman
and Hultmark,
tion has however in Drosophila (Kylsten
1987). Ccc gene transcrip-
been shown to be completely
repressed
only when the flies were grown
axenically
et al., 1990). Northern
used to construct
blot analysis
the medfly cDNA library
of the RNA revealed
only
a very low amount of Ccc-specific mRNA (data not shown). As in Drosophila, this could be accounted for by the possible presence of bacterial contamination in the food. We conclude,
therefore,
that the two cDNAs
in this paper code for medfly homologues
presented
of other insect
Ccc and as such name them Cccl and Cec2.
antibacterial peptides from the female reproductive of the medfly Ceratiris capitata (Insecta, Diptera).
accessory glands Insect Biochem.
Mol. Biol. (1993) in press. Matsumoto,
N., Okada,
M., Takahashi,
H., Ming, Q.X., Nakajima.
Komano, H. and Natori. S.: Molecular assignment of the C-terminal of sarcotoxin protein of Sarcophuga peregrina. Okada, M. and Natori, S.: lonophore
Y.,
cloning of a cDNA and IA, a potent antibacterial
Biochem. J. 239 (1986) 717-722. activity of sarcotoxin I, a bacteri-
cidal of Sarcophagu peregrina. Biochem. J. 260 (1985a)4533458. Okada, M. and Natori, S.: Primary structure of sarcotoxin I, an antibacterial protein induced in hemolymph of Sarcophuga peregrina (flesh fly) larvae. J. Biol. Chem. 260 (1985b) 717447177. Samakovlis, C., Kylsten, P.. Kimbrell. D.A., EngstrBm, A. and Hultmark. D.: The An&pin gene and its product, a male-specific antibacterial peptide in Drosophilu melnnogasrrr. EMBO J. IO (1991) 1633169. Selsted, M.E., Brown, D.M., DeLange, R.G., Harwig, S.S.L. and Lehrer, RI.: Primary structures of six antimicrobial peptides of rabbit peri-
ACKNOWLEDGEMENTS
toneal neutrophils. Steiner, H., H&mark,
Research supported by the Italian National Research Council (CNR), Special Project RAISA, Subproject No. 2, paper No. 1053.
Sequence and specificity of two antibacterial proteins involved in insect immunity. Nature 292 (1981) 2466248. Taniai, K., Kato. Y., Hirochika, H. and Yamakawa. M.: Isolation and
H.G. and H&mark,
H.G.:
nucleotide sequence of cecropin B cDNA clones from the silkworm, Bombyx mori. Biochim. Biophys. Acta 1132 ( 1992) 2033206. Teshima, T., Ueki, Y., Nakai, T., Shiba, T. and Kikuchi, M.: Structure determination of lepidopteran, self-defense substance produced by silkworm. Tetrahedron 42 (1986) 8299834. Tryselius, Y., Samakovlis, C., Kimbrell, D.A. and Hultmak, D.: CecC,
REFERENCES Boman,
J. Biol. Chem. 260 (1985) 457994584. D., Engstrom, A., Bennich, H. and Boman,
D.: Cell-free
Rev. Microbial. 41 (1987) 103-126. Boman, H.G., Boman, LA., Andreu,
immunity
D., Li, Z.-q,
in insects, Annu. Merrifield,
R.B.,
Schlenstedt, G. and Zimmermann, R.: Chemical synthesis and enzymatic processing of precursor forms of cecropins A and B.J. Biol. Chem. 264 (1989) 5852-5860. Craig, A.G.. Engstrom, A., Bennich, H. and Kamensky, I.: Plasma desorption mass spectrometry coupled with sequencing techniques. Biomed. Environ. (1987) 6699673. Hoffmann, J.A. and Hoffmann, D.: The inducible of dipteran insects. Res. Immunol. 141 (1990)
conventional peptide Mass Spectrom. 14 antibacterial 910-918.
peptides
Kylsten, P., Samakovlis, C. and Hultmark, D.: The cecropin locus in Drosophila: a compact gene cluster involved in response to infection. EMBO J. 9 (1990) 2177224. Marchini. D., Giordano, P.C., Amons, R., Bernini, L.F. and Dallai, R.: Purification and primary structure of ceratotoxin A and B, two
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