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The nucleotide sequences of baboon chorionic gonadotropin β-subunit genes have diverged from the human
161
Gene, 46 (1986) 161-169 Elsevier GENE
1732
The nucleotide sequences of baboon chorionic gonadotropin j-subunit human
genes have diverged from the
(Recombinant DNA; multigene family; placenta; placental gene expression; gene conversion; antipregnancy vaccine; A page vectors)
Robert J. Crawford*, Geoffrey W. Tregear and Hugh D. Niall** Howard Florey Institute of Experimental Physiology and Medicine, Universityof Melbourne, Parkville, Victoria 3052 (Australia) Tel. (03) 344-5654 (Received
February
(Revision
received
(Accepted
lOth, 1986) June 20th, 1986)
July 19th, 1986)
SUMMARY
The placental glycopeptide hormone chorionic gonadotropin (CG) is involved in establishing and maintaining pregnancy. The hormone consists of two different non-covalently associated subunits termed a and /I. In man there are seven closely linked genes coding for /ICG-like peptides, but only three of these appear capable of expression in the placenta. The organization of BCG-like genes in man and baboon appears to be similar. We demonstrate here that the baboon genome contains multiple copies (at least five) of /3CG-related genes, and that these genes are closely linked in the genome. Nucleotide sequence data from several BCG cDNA clones indicates that at least two of these BCG-related genes are expressed in the baboon placenta. Analysis of /?CG sequences from baboons and human subjects demonstrates that these genes have diverged markedly between species. In contrast, these sequences are remarkably homogeneous within their respective genomes. Gene conversion events may be responsible for retaining the high degree of identity among the various /?CG gene family members. Knowledge of /?CG sequences from baboon may lead to development of a long-term antipregnancy vaccine. The ability of CG antibodies to interfere with the maintenance of pregnancy can now be investigated within a homologous system.
* To whom
correspondence
and
reprint
requests
should
be
INTRODUCTION
addressed. ** Present
address:
Boulevard,
South
Genentech, San
Inc.,
Francisco,
460 Point CA
San
94080
Bruno
(U.S.A.)
Tel. (415)952-1000. Abbreviations: complementary
aa, amino acid(s); bp, base pair(s); cDNA, to mRNA;
follicle-stimulating
hormone;
mone; nt, nucleotide(s)
0378-l 119/86/$03.50
0
CG, chorionic
gonadotropin;
DNA FSH,
kb, 1000 bp; LH, luteinizing
TSH, thyroid-stimulating
1986 Elsevier
Science Publishers
hor-
hormone.
B.V. (Biomedical
A glycoprotein hormone from the placenta, CG, plays a vital role in early pregnancy by rescuing the corpus luteum and maintaining the synthesis of progesterone (Canfield et al., 1978; Pierce and Parsons, 1981). FSH, LH and TSH, each synthesized in the anterior pituitary, are the other members of the glycoprotein hormone family. Each hormone is composed Division)
162
of two different subunits (termed cc and p) linked non-covalently. The CIsubunits of each hormone are
MATERIALS
identical,
(a) Analysis of baboon DNA
while
responsible
the B subunits
for the physiological
are unique,
and
AND METHODS
specificity (Canlield
et al., 1978). In man, the /3CG subunit
shares about
85 % aa sequence identity with the BLH subunit,
and
Baboon
DNA
was isolated
digested
with restriction
30 % to 40 % identity with the /I subunits of FSH and TSH, respectively. However, it is longer than the /l
Hind111
and
subunits
of the other glycoprotein
an extension C terminus
described
PstI
(Pharmacia)
by Maniatis
hormones,
due to
was
at the
phage 3, Hind111 markers,
(Morgan
et al.,
1975).
The
human
lulose (Southern,
BamHI, using
on
1%
agarose
and
EcoRI,
procedures
et al. (1982). Restricted
of from 25 to 30 aa residues
electrophoresed
from placenta
enzymes
DNA
gels using
transferred
to nitrocel-
1975) and hybridized
with appro-
genome contains a single gene encoding the tl subunit (Fiddes and Goodman, 198 1; Boothby et al., 198 1). In contrast seven BCG-related genes and one BLH gene have been cloned from the human genome (Boorstein et al., 1982; Policastro et al., 1983; Talmadge et al., 1984a).
priate 32P-labelled human /ICG cDNA probes (Maniatis et al., 1982). The human cDNA clone (Fiddes and Goodman, 1980) was kindly provided Dr. J. Fiddes (California Biotechnology, by
We report here an analysis of the BCG sequences in the baboon, (Papio anubis and Papio cyanocephalus) which demonstrates that the baboon genome also contains several /3CG-related genes. Furthermore, nucleotide sequence analysis of several different BCG cDNA clones indicates that at least two of these genes are expressed in the baboon placenta. Comparison of the predicted peptide sequences from baboon with that of man (Fiddes and Goodman, 1980) indicates that a large number of aa differences, many of them nonconservative, have occurred during the relatively short evolutionary period between baboons and human beings. Knowledge of the baboon j3CG sequence has relevance to the development of a long-term antipregnancy vaccine. One approach to contraception relies on the ability to specifically inhibit CG activity.
(b) Preparation
The unique C-terminal extension of the /I subunit provides a specific target for antibody action that should not interfere with the biological activity of the other glycoprotein hormones. Indeed, studies reported by Stevens et al. (198 1) have clearly demonstrated antifertility effects in female baboons immunized with C-terminal peptides of the p subunit of human CG. Data presented here enable the synthesis of peptide fragments corresponding in sequence to the C-terminal extension of baboon BCG. The ability of these peptides to induce antibody production against pregnancy can now be investigated in an homologous system.
Mountain
View, CA). of cDNA library and screening
Baboon (Papio cyanocephalus and Papio anubis) placentae were obtained from Dr. T. Kuehle (San Antonio, TX) and Dr. V. Stevens (Columbus, OH), respectively. Poly(A)+ RNA was isolated from 27-day baboon placentae using guanidinium thiocyanate (Chirgwin et al., 1979). Double-stranded cDNA was synthesized (Gubler and Hoffman, 1983) and cloned into @lo vector (Huynh et al., 1984). The library was probed with human BCG cDNA probes (1977).
RESULTS
as described
by Benton
and Davis
AND DISCUSSION
(a) The number of /KG-related genome
genes in the baboon
Two introns interrupt the human j3CG gene at nt positions 40 and 211 of the corresponding cloned cDNA sequence (Talmadge et al., 1984a) (Fig. 1). A single PslI site, spanning nt 220 through 225, therefore divides the cloned cDNA into one fragment that exclusively encompasses the 3’ exon, and another that contains the entire middle exon (as well as small fragments of the 5’ and 3’ exons). Two separate 32P probes, each containing essentially one of the two human j?CG exons (Fig. 1) were hybridized to genomic baboon DNA previously
163
lntron B
lntron A
23.1 9.4 6.6 4.4
f
2.3 2.03
0.66
-
J
ub
.
m 1234
1234
Fig. 1. Hybridization
of baboon
DNA with 5’ exon and 3’ exon
human BCG cDNA probes. cDNA fragments /KG
exons
acrylamide
were isolated gel electrophoresis
and Goodman, (Maniatis (Taylor
of human
1980). The separate
et al., et al.,
1982),
1976), and
PstI fragments
32P-labelled
using
hybridized
(Southern,
1975). The filters were exposed
probe,
from hybridization respectively.
different 3, HindHI; fragments
baboon
The left-hand
restriction 4, Pstl.
(Papio
enzymes.
baboon Lanes:
film for
autoradiographs
rectangles
DNA digested 1, BamHI;
represent
used as 5’ and 3’ exon probes.
nitrocellulose
with
2, EcoRI;
separate
Triangles
the intron positions
to the PstI site within the human
onto
filters
anubis) DNA
to X-ray
PstI
(labelled
with respect
BCG gene.
(Southern,
(b) The nt and predicted aa sequences placental /ICC cDNAs
of baboon
primers
with the 5’ exon probe and 3’ exon
intron A and intron B) indicate
transferred
(Fiddes
were eluted
random
and right-hand
Lanes contain Striped
separate 8% poly-
to nitrocellulose
restriction
resulted
digested
and
PCG cDNA
containing
7 days at -80°C.
encoding
after PstI digestion
izing gene, then this result further suggests there are more than five baboon flCG-related genes. In support of this interpretation, no PstI sites were observed in the corresponding 3’ exon of several baboon j?CG cDNA clones (Fig. 2 and Table I). EcoRI digestions provided evidence that the BCG genes are closely linked. Both the 5’ and 3’ probes hybridized to a single EcoRI fragment larger than 23 kb (Fig. 1). Results with BarnHI- or HindIIIdigested DNA are consistent with the conclusion that the baboon genome contains multiple copies of closely linked /?CG related genes (Fig. 1). The human genome also contains multiple /?CGrelated genes (seven BCG-like genes and one BLH gene) that are probably all linked within single Sal1 and EcoRI digestion fragments (Boorstein et al., 1982; Talmadge et al., 1984a). Hence the number and linkage of genes hybridizing to 32P-labelled /KG probes are similar in both the baboon and human genomes.
1975).
We
reasoned that the use of single exon probes would result in a close correspondence between the number of hybridizing bands and the number of BCG-related genes in the baboon genome. The 3’ exon probe hybridizes to five PstI fragments of different size, with varying intensity (Fig. 1). This result indicates the presence of multiple /3CG related genes in the baboon genome. If each hybridizing PstI fragment contains a complete 3’ exon, and the darker bands (e.g., the 2.4-kb and 4.4-kb bands, Fig. 1) contain more than one hybrid-
Poly(A) + RNA isolated from a 27-day-old baboon (Papio anubis) placenta was cloned using the RNase H approach to generate second-strand synthesis (Gubler and Hoffman, 1983) and JgtlO vector (Huynh et al., 1984). About 30000 independent clones were screened with 32P-labelled human /KG probes (Fiddes and Goodman, 1980). About one clone in 500 was positive indicating that approx. 0.2% of 27-day placental baboon poly(A)+ RNA contains fiCG sequences. Analysis of several /KG inserts by enzyme digestion and blot hybridization (Southern, 1975) showed that these clones contained inserts ranging in size from 400 bp to 700 bp (not shown). Inserts from these clones were subcloned into M13mp8 or M13mpl0, and the nt sequence in four of the I clones was determined by the dideoxy method (Sanger et al., 1980). The longest clone (Cl) was 642 nt in length, and the complete sequence of this clone is shown in Fig. 2. This clone encodes a peptide similar in structure to human /ICG. The complete translation product is 165 aa which includes a hydrophobic leader sequence characteristic of secretory proteins (Blobel and Dobberstein, 1975; Habener et al., 1978). Furthermore the predicted baboon peptide bears close
1G1u Thr
Met
AA~:~I~~I~A~C;TATAAAC;CC:AC~GTA~~A~I~A~~~~~~A~G~~~~AI::~~~~A~~:I~AA~~~ AT13 GAG
Arg L4u
Trp
ICTG
TOG
Lcu CTG
Lcu ICTG
Lcu CTrj
Cys
Arg
Pro
114
Asn
Ala
TIX
Cl:iC CCC: ATE
AAT
lIil:c
Gly
IIily
:34r M4t A1312 ATI~
-1
Ala 01n C;I;A ~:Arj I;
ICKil: l3;G
)
Lru
lliln
Al::Ci CTC:
Gly
Lcu Leu C:TG CTO
C:ACi 13Xi
1
Ala lX:A
Scr TI,I:
Arg Al:ifi
13111 F’ro L4u Arg I~AI:; I::I:I~ I::TI~ I:I:I:
I+,:, cl::A
L4u I:TI>
Lys
Glu
Ala
lCys
C:ys
Val
Thr
AAG
IIiAlIi I~I~lZ Tl:iT 1~121~ GTlIi I::
Tl3lz
GTIZ
AIZI)
I;ln
Ala
Val GTC
a
Val Asn r-jTt; ,+.,I;
Lcu l;TCi
Thr At;C
Lcu I,TC
Arg lzoc
Pro F’ro Val 1:1;13 CC’C GTI;
Thr ACC
Gly
IXT
13lIiC TGC
Cys TOT
Pro
Gln
I:IX:
C:AG I~TG
Val
Val
Asn
Cys TIX
GTI;
Met ATEi
Arg 011~ I:C;C: I:AI~
TyrAAC: TAI:
PrIII Val
Met ATCi
Arg Cl33
Val CiTG
CTG
Val
Arg
Phc
Glu
I;TG
I::I:~I:: TTI::
I~AI~ TC:l: ATE
Ar-g Cl;fi
Val
Pro
Ala
Cys
Lru
C:AG CilX
C;cr
114
T
Pro
Cys TOT
Lcu Ala Ala lrilu AlI:lz C:TG C;lI:T 1~1~~ GAG
1:~s Pro Thr I14 Cys Ala rIily Tyr A-f11 TI:~T I-J::C: I~I>C: TAt:: TI:~I:: c:l::C ACC
Thr &;I;
A
Thr
Cys
Ala l3lzA
Asp GAT
Pro
Lcu IITC
Asp GAC
Pro
1G1y
Val
Asp
I”C:C; IXT
133:
GTI;
C;AC I,IX
Cys TIX
At-g Cl2c
Pro
Asn His Asn
Val Val Met
Pro
Scr
Val
AT13 13 I3
-‘TC: TIX: IJ
!f;etTIZT
Asp l3AlI
Cys TQT
Ssr 1313: Tl::C
Scr TCT
Arg lzl3c
S4r Al3C
ThrAIZC
Lcu CTC
Gln
Ala
GTT I::IX 1:
Vel
Leu
!Scr
GTC; l:iC:T ICTI:
AI;C: TGT
T
l>GCi GIliT
b-a Lys CCC: AAG
l>AC
His IZAC
b-o IZIZT
Ser TIX
!34r TCA
Lys AAG
Asp I~AC
Pro IXT
Fro 1332
Pro 1332
!jcr AIX
Ala
131~ Thr
Pro
F’he
L~IJ Pro
145 I:;ln
nwr
WA
133C
TTC:
l:TC:
CAA
TAA
131~ IIily
Asp
0
0
Cl:12 AAC c:
CAG
L4u TTlIi
Pro IXT
A
0 PVU WA
Sar AGT
Pro CCA
Ser TCC
Arg CGA
Leu CTC
L4u CTG
Glu Pro GAG CCA A G
AC:C I::I,~
r;CG
Al;GCTTC
TCAATCTGCAAAAAAAA Fig. 2. The nt and predicted into M13mp
8 or Ml3mp
aa sequences
10 (Messing
1980) using either a universal by the solid-phase
The complete
sequence.
Only nt (written
C2 and C3. Asterisks marks
serine
sequence:
Melbourne). sequence
residues
mature
/ICG cDNAs.
or specific baboon
(McBride
using computer
homologous cleavage
to O-linked
to human
glycosylation
primers.
1983) and purified by preparative by Staden
glycosylated
point is shown by a downward
arrow
(Sanger
et al.,
were synthesized
gel electrophoresis.
Sequence
by T. Kyne (Walter
(Papio anubL~) placenta
were
and extend to the poly(A)
above Cl then C2) that differ from Cl are shown for clones
sites (Asn-X-Thr sites within
method Primers
(1977; 1978) and modified
of cDNA derived from a single baboon (written
BCG probe were subcloned
by the dideoxynucleotide
BCG oligodeoxyribonucleotide
developed
nt sequences
from I hybridizing
Clones C2 and C3 begin at nt 135 and 354, respectively,
below Cl then C2) and aa positions N-linked
Inserts
were determined
and Carruthers,
programmes
Three separate
of Cl is shown.
identify consensus
peptide
primer
procedure
and analysed
and Eliza Hall Institute, aligned.
sequencing
phosphoramidite
data were assembled
of baboon
and Vieira, 1982). Sequences
or Asn-X-Ser)
human between
at aa residues
/JCG (Canfield aa -1 and
33 and 50. The letter 0
et al., 1978). The proposed
+ 1.
leader
165
TABLE
I
Nucleotide
differences
in baboon Position
cDNA
clone b
/KG
cDNA
clones
of nt difference a
184
257
A
N
N
B
N
N
341
344
423
434
528
596
634
N
N
N
N
A
G
C
N
N
G
C
A
A
T
Cl
A
T
C
G
A
T
A
G
T
c2
G
C
A
T
G
C
C
A
T
c3
N
N
N
N
G
T
A
G
T
a Positions prepared
of nt differences and isolated
are numbered
as described
according
in MATERIALS
to Fig. 2. N indicate AND METHODS,
undetermined
nt in short cDNA
and nt sequences
clones. cDNA
clones were
as described
in the legend
were determined
to Fig. 2. b Clones, A and B originate
from separate
Pupio cyanocephalus placentae.
Clones Cl, C2 and C3 were derived from a single Pupio anubis
placenta.
similarity to the human /?CG peptide (Fiddes and Goodman, 1980). We therefore conclude that this cDNA clone codes for a baboon flCG peptide. Each of the other cDNA clones sequenced are shorter than clone Cl. One is 382 nt in length, and is identical in sequence to clone Cl. The other two clones contain sequence differences when compared to Cl. Clone C2 contains a sequence that encodes a complete /KG peptide, but lacked the two 5’-terminal codons of the leader peptide, and clone C3 extends from nt 354 to 642 when compared to Cl (Fig. 2). The nt differences are apparent at eight positions when the sequences of the three separate Papio anubis PCG clones are compared (Table I; Fig. 2). Three of the eight nt differences result in aa changes. The single nt difference between Cl and C3 (at nt 423, Fig. 2) alters the Met residue in Cl to Val. This change, as well as two additional aa differences are apparent when Cl is compared to C2 (Fig. 2). His replaces the Asn residue of Cl (nt change at 528, Fig. 2) and within the leader sequence the Cl Gln residue is changed to Arg (nt position 184, Fig. 2). Clones Cl and C2 encode complete /?CG peptides. Within the hormone-coding region these clones differ at 7 nt positions (1.6%) and 2 aa positions (1.4%) (Table II). A different baboon species (Papio cyanocephalus) was used to prepare two additional cDNA clone banks, and one /KG clone was analysed from each.
The nt sequences of these two clones differ from each of the Papio anubis clones (Table I). However, the peptide sequences predicted from the Papio cyanocephalus clones are identical with the correTABLE
II
Baboon
and human
Comparison
HPCG Hj?CG
a
:BabBCG-Cl :BabBCG-C2
Babj3CG-Cl: HBCG
)?CG comparison
BabBCG-C2
: HfiLH
nt changes”
aa changes’
(%)
(%)
43/438 (9.8)
27/145 (18.6)
40/438 (9.1)
26/145 (17.9)
7/438 (1.6)
2/145 ( 1.4)
26/334 (7.8)
17/115 (14.8)
a BCG comparisons
were made over the hormone
coding region,
from
start
1 up
(Figr3).
The
HBLH
: HBCG comparison
was made over the homologous
hor-
codon
mone-coding
to
region from codon
nt deletion
codon
number
ratio
146
1 up to codon 94, where a single
in the BCG gene accounts
results in the )?CG C-terminal b The
stop
for the frameshift
extension
of different
(Talmadge
nt
was
that
et al., 1984a)
determined
from
total nt BabfiCG-Cl H/KG
and BabfiCG-C2
and HBLH comparisons
of Fiddes
and Goodman
cDNA sequences
shown in Fig. 2.
were determined
from the data
(1980) and Talmadge
et al. (1984a),
respectively. c The ratio
number
of aa differences
was determined
from pep-
total aa tide sequences
predicted
from the cDNAs
from the data
of Fiddes
and Goodman
et al. (1984a).
shown in Fig. 2 and (1980) and Talmadge
166
sponding region of peptide C3 from Papio anubis. Knowledge of baboon /?CG sequences will allow antipregnancy vaccine studies (Stevens et al., 1981) to proceed in an homologous system. It is particularly relevant to these studies that the predicted BCG C-terminal peptide sequence is identical for each of five different cDNA clones from two species of baboon. (c) At least two /KC
genes are expressed
in the
baboon placenta
Three different /?CG cDNA clones (Cl, C2 and C3) were isolated from a library derived from a single baboon placenta. Two of these clones (Cl and C2) showed differences at 8 nt positions, while the third clone (C3) was different to clone Cl at only 1 of 5 nt positions compared (Table I). It is possible that differences between any two of the clones are polymorphic and that these clones are products of separate alleles. It follows that the third clone originates from a non-allelic gene. It is also possible that the three clones result from transcription of three separate /?CG genes. Regardless of these alternatives, it is clear that more than one PCG related gene is expressed in the baboon placenta. These data are in agreement with that from human subjects where two different /?CG mRNAs from separate genes were also detected in the lirsttrimester placenta. Additional evidence suggests that no more than three of the seven human /?CG-like genes are active in the placenta (Talmadge et al., the additional genes are 1984b). Whether pseudogenes, or expressed in other tissues remains to be determined. Simultaneous expression of more than one /?CG-like gene in the placenta suggests that the peptides might exert separate hormonal effects. Hence it may be worthwhile to investigate whether differences in the biological activities of the respective peptides can be detected. Such differences may be difficult to demonstrate considering their nearidentical peptide sequence. It is also possible that separate PCG-like genes are expressed within the placenta at varying stages of pregnancy. This would explain, at least to some extent, why the baboon and human genomes contain multiple BCG-related genes. This possibility could be investigated by determining the nt sequence of PCG mRNAs within placenta both older and younger than the 25 to 30 day tissue used here.
(d) Comparison
of baboon
and human
/XC
se-
quences
A total of 49 nt differences are apparent when the coding region of baboon /?CG clone Cl is compared to that of man (Fig. 3). There are 43 (9.8%) nt differences in the hormone region, resulting in 27 aa (18.6%) differences (Fig. 3; Table II). Similarly the extent of nt and aa variation between baboon clone C2 and human is 9.1% and 17.9x, respectively (Table II). This level of difference contrasts with the closer similarity between some other baboon and human peptides. For example about 4% and 7% diversity is observed when B globin (Nute and Mahoney, 1980; Braunitzer et al., 1961) and a-1-antitrypsin (Kurachi et al., 1981; Bollen et al., 1983) peptides are aligned, respectively. Many of these differences are non-conservative in nature. For example aa residues 8 and 83 are Leu and Pro in baboon and Arg and Ala in man (Fig. 3). Despite the many aa differences, the hydropathy profiles (Kyte and Doolittle, 1982) of the baboon and human BCG peptides are virtually identical (Fig. 4). These profiles illustrate that the two most hydrophobic regions of the hormone (apart from the leader sequence) are localised approximately between aa residues 23 and 57 and residues 75 and 93. The most hydrophilic region covers the C-terminal portion of the peptide from about Cys residue 93 to about Gly 139. One particular aa difference between the peptides is noteworthy. It has been suggested that an Ala codon instead of Asp at aa position 117 in the human peptide, correlates with nonexpression in the human placenta (Talmadge et al., 1984b). This is clearly not the case in baboon because each of the baboon BCG cDNAs sequenced contain an Ala codon at this position. (e) Evolution of /KG genes
The pituitary glycoprotein hormones are synthesized in a wide range of species, whereas placental CG synthesis appears restricted to certain mammals (Canfield et al., 1978; Pierce and Parsons, 1981). Hence PCG is believed to be the most recently evolved member of the glycoprotein hormone /? subunit family. At least in man CG most closely resembles LH in structure (Dayhoff, 1976) and
VP1
36
Ila
Asn
Ala
Thr
Leu
Ala
Ala
I;I:I:
ATC
AAT
oc:c
ACI:
I:TF
C;IX
Ile
Cys
Ala
Gly
Tyr
TI>T
rjtX
1:~s At-g Fra TljC
C132
Val
Asn
Thr
Thr
ijTC
AAC
ACC
AI::I: ATI:
Lys
131~ Ala
I;C:I: I;AI~ TO
AAG
l>Al2 l?l~l~: Tl:iT l::l~:l: l>Tl> 1: G
Cys
Pro
Thr
Met
IXC
TAC: TOI:
l::lX
AN:
ATl_7 ATI> lZl3E l3TG t: t: 1:
Val
Val
Asn
Tyr
Arg
ASP Olu
Val
Arg
Pha
Glu
GTC
t3Trj
l:y!tt TtX
AAC
TAC
IZuC
l:AG
OTt2
IZcic
TTC:
GAG
Tyr Val
Ala Pro
Val
Ala
*
Ala Leu Lcu Pro Fro Val Pro rjln tzTt3 CCC CCC GTCi Cl~l~ CAG t: T 12
Lcu
Pro
C;ly
Cys
Pro
CTI=
CCT
GOC
TGC
CtX
I3 1 n Arg Cys
Ala
Leu
t:fiC
t;CA
CTC
TI>T
Arg Fro
Thr Mat
Cys
Ar’g
Pro
Val
Val
Lcu
Asn Asp
cily
Val
CCT t;c
tXtc.
GTG
GAI: A
Cys
Arg
Arg
Scr
TGC.
t;GC
CTjl:
AtX
Thr AtX
Fro t:tX
Val Met
Val
ATIS t:
GTC
!Ser Tt:T
Ser TtX
Asp
t::ys tily
t;Ar;
TOT
Arg Phe Asp Asp Pru Asn Lcu t3AT GAC CCC AAC: CTr, CG T
Leu
CGA
CTtZ
I>TI~ A
01n
Thr AIX
Gl y Ala Val l3tX t>
CiTtZ
:Ser
Ile
Arg
TCC
ATC
Ct>G
Leu
Ser
ASP Gin Ala CAG GtX A
tGTtIi GC:T t::TC AGC
01~
Fro
Lys
Asp
His
CCC
AAG
t3At:
CAC: XT
tGt37 tXiT
Fro Lru
Oly Glu
Cl73 1:
GAG G
Ala
0 !&r
Ser
Lys
Tt::C Tt:T
TW
TCA
AAG
Pra
11s Phe
Pro
Ser Ala
Asp rjly
Thr
CCA
WA
t:t3C
AtX
CTG
Fro
A
TOT
LWJ
TTtz t;
Set-
!&r
Cys
rjTT CCC TAC: Ci
Asp GAC 1:
Pro CCT
F’ro CCC
Fro CtX
Leu t;C:o TTC: CTI: A
Pro
14.3 rjln
)ew
lXt3
CAA
TAA
0 Arg
Tl>ll
t:
A
Pro Ssr Fro,Ser CCA At3T CCA TCC
Val
1Z:TG IZAG
Thr
0
Cys
T
AA
Thr CYS ACC TGT
IlC
GlY
Glu.
0
Let1
!%r AGC
Fr-a CCT T
AiX:TTC
A
Fig. 3. The nt and predicted aa sequences of baboon and human jCG subunits. The sequences of baboon jCG clone Cl (see Fig. 2) are aligned with those of human fiCG (Fiddes and Goodman, 1980). Only those positions which differ from baboon BCG are shown for the human sequence (nt differences below and aa replacement substitutions above the baboon sequence). Asterisks and letters 0 identify N-linked and O-linked glycosylation sites, respectively. The Ser residue at aa 158 is O-linked glycosylated in man (Canfield et al., 1978). The aa residue at this position in the baboon is Ala.
biological activity (Pierce and Parsons, 1981). This clone similarity is also apparent in the gene sequences of the respective fi subunits (Talmadge et al., 1984a). It is therefore likely that the jS33 gene originated by duplication of an ancestral BLH-like and gene, and that subsequent duplications rearrangements of the PCG gene were responsible
for the /?CG multigene family detected in humans and baboons. The evolutionary events from the point of fiCG$LH divergence are not clear. These events have resulted in a marked divergence of /KG-related genes between baboon and human. (In fact human PCG more closely resembles human /?LH (92.2% nt
168
It is significant
that a high proportion
of replace-
ment changes has occurred between human and baboon /?CG-genes; of 43 nt differences in the hormone
coding
region,
30 are replacement.
more many of the aa changes suggesting the
Hydropathy
B
Fig. 4. Hydropathy Doolittle
Sequences
were
analysed
(1982) using the computer
(A) Baboon
BCG; (B) human
human
and baboon
according programme
to Kyte
/XC and
of Dr. T. Kyne.
BCG.
and 85.2% aa homology) than baboon /?CG (90-91x nt and 82% aa homology; Table II). In contrast the sequences of /?CG-related genes within species (baboon or human) are very similar. These observations suggest that recombinational events, equal crossing-over or gene conversion events which may have resulted in the present BCG gene family, occurred much later than the primary /?CG//?LH duplication, and after the evolutionary divergence of baboon and man. However, this evolutionary course is unlikely because the j?CG gene duplication probably occurred soon after the separation of /3CG and /?LH genes, since the divergence rate of the introns from human PCG genes 5 and 6 is similar to that of PLH and fiCG introns (Talmadge et al., 1984a). Hence it is not clear how divergence of /?CG genes proceeded between species while maintaining sequence conservation within species. It is possible that gene conversion, which can operate to maintain homogeneity within a gene family (Slightom et al., 1980) has been involved in conserving j?CG sequences within species. However, such a conversion process has excluded the PLH gene, despite the close physical linkage of /?LH and PCG-like genes.
sequence
of BCG
explanations
First,
CG
may be under less selective pressure
than
hormonal
possible.
species.
Several
other
are
between
functions most
plot of aligned
that there is not a strict need to conserve
peptide
receptor
peptides.
Further-
are nonconservative,
activities.
may be capable
Second,
of responding
the CG to hetero-
geneous CG-related peptides, thus allowing the evolution of diverse CG-like peptides. The likelihood of this suggestion is supported by the observation that LH is capable of exerting CG-like activities (Pierce and Parsons, 1981) despite the high degree of sequence divergence between human /?LH and j?CG peptides (Table II). Alternatively selective pressure may act on the interaction between the CG peptide and its receptor rather than the flCG sequence alone. Divergence of BCG sequences between species would then be permitted if the BCG sequence and its receptor evolved congruently.
ACKNOWLEDGEMENTS
We thank Dr. T. Kuehl (San Antonio, TX) and Dr. V. Stevens (Ohio State University, Columbus, OH) for providing baboon placentae, and Dr. J. Fiddes for allowing the use of the human /?CG cDNA clone. We are grateful for the excellent technical assistance of Vicki Hammond and Lucy Duncan, and to Dr. Tony Kyne for use of computer programmes. This work was supported in part by the Special Programme for Research in Human Reproduction, World Health Organisation, and by the National Health and Medical Research Council of Australia.
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Maniatis,T.,
Gene, 46 (1986) 161-169 Elsevier GENE
1732
The nucleotide sequences of baboon chorionic gonadotropin j-subunit human
genes have diverged from the
(Recombinant DNA; multigene family; placenta; placental gene expression; gene conversion; antipregnancy vaccine; A page vectors)
Robert J. Crawford*, Geoffrey W. Tregear and Hugh D. Niall** Howard Florey Institute of Experimental Physiology and Medicine, Universityof Melbourne, Parkville, Victoria 3052 (Australia) Tel. (03) 344-5654 (Received
February
(Revision
received
(Accepted
lOth, 1986) June 20th, 1986)
July 19th, 1986)
SUMMARY
The placental glycopeptide hormone chorionic gonadotropin (CG) is involved in establishing and maintaining pregnancy. The hormone consists of two different non-covalently associated subunits termed a and /I. In man there are seven closely linked genes coding for /ICG-like peptides, but only three of these appear capable of expression in the placenta. The organization of BCG-like genes in man and baboon appears to be similar. We demonstrate here that the baboon genome contains multiple copies (at least five) of /3CG-related genes, and that these genes are closely linked in the genome. Nucleotide sequence data from several BCG cDNA clones indicates that at least two of these BCG-related genes are expressed in the baboon placenta. Analysis of /?CG sequences from baboons and human subjects demonstrates that these genes have diverged markedly between species. In contrast, these sequences are remarkably homogeneous within their respective genomes. Gene conversion events may be responsible for retaining the high degree of identity among the various /?CG gene family members. Knowledge of /?CG sequences from baboon may lead to development of a long-term antipregnancy vaccine. The ability of CG antibodies to interfere with the maintenance of pregnancy can now be investigated within a homologous system.
* To whom
correspondence
and
reprint
requests
should
be
INTRODUCTION
addressed. ** Present
address:
Boulevard,
South
Genentech, San
Inc.,
Francisco,
460 Point CA
San
94080
Bruno
(U.S.A.)
Tel. (415)952-1000. Abbreviations: complementary
aa, amino acid(s); bp, base pair(s); cDNA, to mRNA;
follicle-stimulating
hormone;
mone; nt, nucleotide(s)
0378-l 119/86/$03.50
0
CG, chorionic
gonadotropin;
DNA FSH,
kb, 1000 bp; LH, luteinizing
TSH, thyroid-stimulating
1986 Elsevier
Science Publishers
hor-
hormone.
B.V. (Biomedical
A glycoprotein hormone from the placenta, CG, plays a vital role in early pregnancy by rescuing the corpus luteum and maintaining the synthesis of progesterone (Canfield et al., 1978; Pierce and Parsons, 1981). FSH, LH and TSH, each synthesized in the anterior pituitary, are the other members of the glycoprotein hormone family. Each hormone is composed Division)
162
of two different subunits (termed cc and p) linked non-covalently. The CIsubunits of each hormone are
MATERIALS
identical,
(a) Analysis of baboon DNA
while
responsible
the B subunits
for the physiological
are unique,
and
AND METHODS
specificity (Canlield
et al., 1978). In man, the /3CG subunit
shares about
85 % aa sequence identity with the BLH subunit,
and
Baboon
DNA
was isolated
digested
with restriction
30 % to 40 % identity with the /I subunits of FSH and TSH, respectively. However, it is longer than the /l
Hind111
and
subunits
of the other glycoprotein
an extension C terminus
described
PstI
(Pharmacia)
by Maniatis
hormones,
due to
was
at the
phage 3, Hind111 markers,
(Morgan
et al.,
1975).
The
human
lulose (Southern,
BamHI, using
on
1%
agarose
and
EcoRI,
procedures
et al. (1982). Restricted
of from 25 to 30 aa residues
electrophoresed
from placenta
enzymes
DNA
gels using
transferred
to nitrocel-
1975) and hybridized
with appro-
genome contains a single gene encoding the tl subunit (Fiddes and Goodman, 198 1; Boothby et al., 198 1). In contrast seven BCG-related genes and one BLH gene have been cloned from the human genome (Boorstein et al., 1982; Policastro et al., 1983; Talmadge et al., 1984a).
priate 32P-labelled human /ICG cDNA probes (Maniatis et al., 1982). The human cDNA clone (Fiddes and Goodman, 1980) was kindly provided Dr. J. Fiddes (California Biotechnology, by
We report here an analysis of the BCG sequences in the baboon, (Papio anubis and Papio cyanocephalus) which demonstrates that the baboon genome also contains several /3CG-related genes. Furthermore, nucleotide sequence analysis of several different BCG cDNA clones indicates that at least two of these genes are expressed in the baboon placenta. Comparison of the predicted peptide sequences from baboon with that of man (Fiddes and Goodman, 1980) indicates that a large number of aa differences, many of them nonconservative, have occurred during the relatively short evolutionary period between baboons and human beings. Knowledge of the baboon j3CG sequence has relevance to the development of a long-term antipregnancy vaccine. One approach to contraception relies on the ability to specifically inhibit CG activity.
(b) Preparation
The unique C-terminal extension of the /I subunit provides a specific target for antibody action that should not interfere with the biological activity of the other glycoprotein hormones. Indeed, studies reported by Stevens et al. (198 1) have clearly demonstrated antifertility effects in female baboons immunized with C-terminal peptides of the p subunit of human CG. Data presented here enable the synthesis of peptide fragments corresponding in sequence to the C-terminal extension of baboon BCG. The ability of these peptides to induce antibody production against pregnancy can now be investigated in an homologous system.
Mountain
View, CA). of cDNA library and screening
Baboon (Papio cyanocephalus and Papio anubis) placentae were obtained from Dr. T. Kuehle (San Antonio, TX) and Dr. V. Stevens (Columbus, OH), respectively. Poly(A)+ RNA was isolated from 27-day baboon placentae using guanidinium thiocyanate (Chirgwin et al., 1979). Double-stranded cDNA was synthesized (Gubler and Hoffman, 1983) and cloned into @lo vector (Huynh et al., 1984). The library was probed with human BCG cDNA probes (1977).
RESULTS
as described
by Benton
and Davis
AND DISCUSSION
(a) The number of /KG-related genome
genes in the baboon
Two introns interrupt the human j3CG gene at nt positions 40 and 211 of the corresponding cloned cDNA sequence (Talmadge et al., 1984a) (Fig. 1). A single PslI site, spanning nt 220 through 225, therefore divides the cloned cDNA into one fragment that exclusively encompasses the 3’ exon, and another that contains the entire middle exon (as well as small fragments of the 5’ and 3’ exons). Two separate 32P probes, each containing essentially one of the two human j?CG exons (Fig. 1) were hybridized to genomic baboon DNA previously
163
lntron B
lntron A
23.1 9.4 6.6 4.4
f
2.3 2.03
0.66
-
J
ub
.
m 1234
1234
Fig. 1. Hybridization
of baboon
DNA with 5’ exon and 3’ exon
human BCG cDNA probes. cDNA fragments /KG
exons
acrylamide
were isolated gel electrophoresis
and Goodman, (Maniatis (Taylor
of human
1980). The separate
et al., et al.,
1982),
1976), and
PstI fragments
32P-labelled
using
hybridized
(Southern,
1975). The filters were exposed
probe,
from hybridization respectively.
different 3, HindHI; fragments
baboon
The left-hand
restriction 4, Pstl.
(Papio
enzymes.
baboon Lanes:
film for
autoradiographs
rectangles
DNA digested 1, BamHI;
represent
used as 5’ and 3’ exon probes.
nitrocellulose
with
2, EcoRI;
separate
Triangles
the intron positions
to the PstI site within the human
onto
filters
anubis) DNA
to X-ray
PstI
(labelled
with respect
BCG gene.
(Southern,
(b) The nt and predicted aa sequences placental /ICC cDNAs
of baboon
primers
with the 5’ exon probe and 3’ exon
intron A and intron B) indicate
transferred
(Fiddes
were eluted
random
and right-hand
Lanes contain Striped
separate 8% poly-
to nitrocellulose
restriction
resulted
digested
and
PCG cDNA
containing
7 days at -80°C.
encoding
after PstI digestion
izing gene, then this result further suggests there are more than five baboon flCG-related genes. In support of this interpretation, no PstI sites were observed in the corresponding 3’ exon of several baboon j?CG cDNA clones (Fig. 2 and Table I). EcoRI digestions provided evidence that the BCG genes are closely linked. Both the 5’ and 3’ probes hybridized to a single EcoRI fragment larger than 23 kb (Fig. 1). Results with BarnHI- or HindIIIdigested DNA are consistent with the conclusion that the baboon genome contains multiple copies of closely linked /?CG related genes (Fig. 1). The human genome also contains multiple /?CGrelated genes (seven BCG-like genes and one BLH gene) that are probably all linked within single Sal1 and EcoRI digestion fragments (Boorstein et al., 1982; Talmadge et al., 1984a). Hence the number and linkage of genes hybridizing to 32P-labelled /KG probes are similar in both the baboon and human genomes.
1975).
We
reasoned that the use of single exon probes would result in a close correspondence between the number of hybridizing bands and the number of BCG-related genes in the baboon genome. The 3’ exon probe hybridizes to five PstI fragments of different size, with varying intensity (Fig. 1). This result indicates the presence of multiple /3CG related genes in the baboon genome. If each hybridizing PstI fragment contains a complete 3’ exon, and the darker bands (e.g., the 2.4-kb and 4.4-kb bands, Fig. 1) contain more than one hybrid-
Poly(A) + RNA isolated from a 27-day-old baboon (Papio anubis) placenta was cloned using the RNase H approach to generate second-strand synthesis (Gubler and Hoffman, 1983) and JgtlO vector (Huynh et al., 1984). About 30000 independent clones were screened with 32P-labelled human /KG probes (Fiddes and Goodman, 1980). About one clone in 500 was positive indicating that approx. 0.2% of 27-day placental baboon poly(A)+ RNA contains fiCG sequences. Analysis of several /KG inserts by enzyme digestion and blot hybridization (Southern, 1975) showed that these clones contained inserts ranging in size from 400 bp to 700 bp (not shown). Inserts from these clones were subcloned into M13mp8 or M13mpl0, and the nt sequence in four of the I clones was determined by the dideoxy method (Sanger et al., 1980). The longest clone (Cl) was 642 nt in length, and the complete sequence of this clone is shown in Fig. 2. This clone encodes a peptide similar in structure to human /ICG. The complete translation product is 165 aa which includes a hydrophobic leader sequence characteristic of secretory proteins (Blobel and Dobberstein, 1975; Habener et al., 1978). Furthermore the predicted baboon peptide bears close
1G1u Thr
Met
AA~:~I~~I~A~C;TATAAAC;CC:AC~GTA~~A~I~A~~~~~~A~G~~~~AI::~~~~A~~:I~AA~~~ AT13 GAG
Arg L4u
Trp
ICTG
TOG
Lcu CTG
Lcu ICTG
Lcu CTrj
Cys
Arg
Pro
114
Asn
Ala
TIX
Cl:iC CCC: ATE
AAT
lIil:c
Gly
IIily
:34r M4t A1312 ATI~
-1
Ala 01n C;I;A ~:Arj I;
ICKil: l3;G
)
Lru
lliln
Al::Ci CTC:
Gly
Lcu Leu C:TG CTO
C:ACi 13Xi
1
Ala lX:A
Scr TI,I:
Arg Al:ifi
13111 F’ro L4u Arg I~AI:; I::I:I~ I::TI~ I:I:I:
I+,:, cl::A
L4u I:TI>
Lys
Glu
Ala
lCys
C:ys
Val
Thr
AAG
IIiAlIi I~I~lZ Tl:iT 1~121~ GTlIi I::
Tl3lz
GTIZ
AIZI)
I;ln
Ala
Val GTC
a
Val Asn r-jTt; ,+.,I;
Lcu l;TCi
Thr At;C
Lcu I,TC
Arg lzoc
Pro F’ro Val 1:1;13 CC’C GTI;
Thr ACC
Gly
IXT
13lIiC TGC
Cys TOT
Pro
Gln
I:IX:
C:AG I~TG
Val
Val
Asn
Cys TIX
GTI;
Met ATEi
Arg 011~ I:C;C: I:AI~
TyrAAC: TAI:
PrIII Val
Met ATCi
Arg Cl33
Val CiTG
CTG
Val
Arg
Phc
Glu
I;TG
I::I:~I:: TTI::
I~AI~ TC:l: ATE
Ar-g Cl;fi
Val
Pro
Ala
Cys
Lru
C:AG CilX
C;cr
114
T
Pro
Cys TOT
Lcu Ala Ala lrilu AlI:lz C:TG C;lI:T 1~1~~ GAG
1:~s Pro Thr I14 Cys Ala rIily Tyr A-f11 TI:~T I-J::C: I~I>C: TAt:: TI:~I:: c:l::C ACC
Thr &;I;
A
Thr
Cys
Ala l3lzA
Asp GAT
Pro
Lcu IITC
Asp GAC
Pro
1G1y
Val
Asp
I”C:C; IXT
133:
GTI;
C;AC I,IX
Cys TIX
At-g Cl2c
Pro
Asn His Asn
Val Val Met
Pro
Scr
Val
AT13 13 I3
-‘TC: TIX: IJ
!f;etTIZT
Asp l3AlI
Cys TQT
Ssr 1313: Tl::C
Scr TCT
Arg lzl3c
S4r Al3C
ThrAIZC
Lcu CTC
Gln
Ala
GTT I::IX 1:
Vel
Leu
!Scr
GTC; l:iC:T ICTI:
AI;C: TGT
T
l>GCi GIliT
b-a Lys CCC: AAG
l>AC
His IZAC
b-o IZIZT
Ser TIX
!34r TCA
Lys AAG
Asp I~AC
Pro IXT
Fro 1332
Pro 1332
!jcr AIX
Ala
131~ Thr
Pro
F’he
L~IJ Pro
145 I:;ln
nwr
WA
133C
TTC:
l:TC:
CAA
TAA
131~ IIily
Asp
0
0
Cl:12 AAC c:
CAG
L4u TTlIi
Pro IXT
A
0 PVU WA
Sar AGT
Pro CCA
Ser TCC
Arg CGA
Leu CTC
L4u CTG
Glu Pro GAG CCA A G
AC:C I::I,~
r;CG
Al;GCTTC
TCAATCTGCAAAAAAAA Fig. 2. The nt and predicted into M13mp
8 or Ml3mp
aa sequences
10 (Messing
1980) using either a universal by the solid-phase
The complete
sequence.
Only nt (written
C2 and C3. Asterisks marks
serine
sequence:
Melbourne). sequence
residues
mature
/ICG cDNAs.
or specific baboon
(McBride
using computer
homologous cleavage
to O-linked
to human
glycosylation
primers.
1983) and purified by preparative by Staden
glycosylated
point is shown by a downward
arrow
(Sanger
et al.,
were synthesized
gel electrophoresis.
Sequence
by T. Kyne (Walter
(Papio anubL~) placenta
were
and extend to the poly(A)
above Cl then C2) that differ from Cl are shown for clones
sites (Asn-X-Thr sites within
method Primers
(1977; 1978) and modified
of cDNA derived from a single baboon (written
BCG probe were subcloned
by the dideoxynucleotide
BCG oligodeoxyribonucleotide
developed
nt sequences
from I hybridizing
Clones C2 and C3 begin at nt 135 and 354, respectively,
below Cl then C2) and aa positions N-linked
Inserts
were determined
and Carruthers,
programmes
Three separate
of Cl is shown.
identify consensus
peptide
primer
procedure
and analysed
and Eliza Hall Institute, aligned.
sequencing
phosphoramidite
data were assembled
of baboon
and Vieira, 1982). Sequences
or Asn-X-Ser)
human between
at aa residues
/JCG (Canfield aa -1 and
33 and 50. The letter 0
et al., 1978). The proposed
+ 1.
leader
165
TABLE
I
Nucleotide
differences
in baboon Position
cDNA
clone b
/KG
cDNA
clones
of nt difference a
184
257
A
N
N
B
N
N
341
344
423
434
528
596
634
N
N
N
N
A
G
C
N
N
G
C
A
A
T
Cl
A
T
C
G
A
T
A
G
T
c2
G
C
A
T
G
C
C
A
T
c3
N
N
N
N
G
T
A
G
T
a Positions prepared
of nt differences and isolated
are numbered
as described
according
in MATERIALS
to Fig. 2. N indicate AND METHODS,
undetermined
nt in short cDNA
and nt sequences
clones. cDNA
clones were
as described
in the legend
were determined
to Fig. 2. b Clones, A and B originate
from separate
Pupio cyanocephalus placentae.
Clones Cl, C2 and C3 were derived from a single Pupio anubis
placenta.
similarity to the human /?CG peptide (Fiddes and Goodman, 1980). We therefore conclude that this cDNA clone codes for a baboon flCG peptide. Each of the other cDNA clones sequenced are shorter than clone Cl. One is 382 nt in length, and is identical in sequence to clone Cl. The other two clones contain sequence differences when compared to Cl. Clone C2 contains a sequence that encodes a complete /KG peptide, but lacked the two 5’-terminal codons of the leader peptide, and clone C3 extends from nt 354 to 642 when compared to Cl (Fig. 2). The nt differences are apparent at eight positions when the sequences of the three separate Papio anubis PCG clones are compared (Table I; Fig. 2). Three of the eight nt differences result in aa changes. The single nt difference between Cl and C3 (at nt 423, Fig. 2) alters the Met residue in Cl to Val. This change, as well as two additional aa differences are apparent when Cl is compared to C2 (Fig. 2). His replaces the Asn residue of Cl (nt change at 528, Fig. 2) and within the leader sequence the Cl Gln residue is changed to Arg (nt position 184, Fig. 2). Clones Cl and C2 encode complete /?CG peptides. Within the hormone-coding region these clones differ at 7 nt positions (1.6%) and 2 aa positions (1.4%) (Table II). A different baboon species (Papio cyanocephalus) was used to prepare two additional cDNA clone banks, and one /KG clone was analysed from each.
The nt sequences of these two clones differ from each of the Papio anubis clones (Table I). However, the peptide sequences predicted from the Papio cyanocephalus clones are identical with the correTABLE
II
Baboon
and human
Comparison
HPCG Hj?CG
a
:BabBCG-Cl :BabBCG-C2
Babj3CG-Cl: HBCG
)?CG comparison
BabBCG-C2
: HfiLH
nt changes”
aa changes’
(%)
(%)
43/438 (9.8)
27/145 (18.6)
40/438 (9.1)
26/145 (17.9)
7/438 (1.6)
2/145 ( 1.4)
26/334 (7.8)
17/115 (14.8)
a BCG comparisons
were made over the hormone
coding region,
from
start
1 up
(Figr3).
The
HBLH
: HBCG comparison
was made over the homologous
hor-
codon
mone-coding
to
region from codon
nt deletion
codon
number
ratio
146
1 up to codon 94, where a single
in the BCG gene accounts
results in the )?CG C-terminal b The
stop
for the frameshift
extension
of different
(Talmadge
nt
was
that
et al., 1984a)
determined
from
total nt BabfiCG-Cl H/KG
and BabfiCG-C2
and HBLH comparisons
of Fiddes
and Goodman
cDNA sequences
shown in Fig. 2.
were determined
from the data
(1980) and Talmadge
et al. (1984a),
respectively. c The ratio
number
of aa differences
was determined
from pep-
total aa tide sequences
predicted
from the cDNAs
from the data
of Fiddes
and Goodman
et al. (1984a).
shown in Fig. 2 and (1980) and Talmadge
166
sponding region of peptide C3 from Papio anubis. Knowledge of baboon /?CG sequences will allow antipregnancy vaccine studies (Stevens et al., 1981) to proceed in an homologous system. It is particularly relevant to these studies that the predicted BCG C-terminal peptide sequence is identical for each of five different cDNA clones from two species of baboon. (c) At least two /KC
genes are expressed
in the
baboon placenta
Three different /?CG cDNA clones (Cl, C2 and C3) were isolated from a library derived from a single baboon placenta. Two of these clones (Cl and C2) showed differences at 8 nt positions, while the third clone (C3) was different to clone Cl at only 1 of 5 nt positions compared (Table I). It is possible that differences between any two of the clones are polymorphic and that these clones are products of separate alleles. It follows that the third clone originates from a non-allelic gene. It is also possible that the three clones result from transcription of three separate /?CG genes. Regardless of these alternatives, it is clear that more than one PCG related gene is expressed in the baboon placenta. These data are in agreement with that from human subjects where two different /?CG mRNAs from separate genes were also detected in the lirsttrimester placenta. Additional evidence suggests that no more than three of the seven human /?CG-like genes are active in the placenta (Talmadge et al., the additional genes are 1984b). Whether pseudogenes, or expressed in other tissues remains to be determined. Simultaneous expression of more than one /?CG-like gene in the placenta suggests that the peptides might exert separate hormonal effects. Hence it may be worthwhile to investigate whether differences in the biological activities of the respective peptides can be detected. Such differences may be difficult to demonstrate considering their nearidentical peptide sequence. It is also possible that separate PCG-like genes are expressed within the placenta at varying stages of pregnancy. This would explain, at least to some extent, why the baboon and human genomes contain multiple BCG-related genes. This possibility could be investigated by determining the nt sequence of PCG mRNAs within placenta both older and younger than the 25 to 30 day tissue used here.
(d) Comparison
of baboon
and human
/XC
se-
quences
A total of 49 nt differences are apparent when the coding region of baboon /?CG clone Cl is compared to that of man (Fig. 3). There are 43 (9.8%) nt differences in the hormone region, resulting in 27 aa (18.6%) differences (Fig. 3; Table II). Similarly the extent of nt and aa variation between baboon clone C2 and human is 9.1% and 17.9x, respectively (Table II). This level of difference contrasts with the closer similarity between some other baboon and human peptides. For example about 4% and 7% diversity is observed when B globin (Nute and Mahoney, 1980; Braunitzer et al., 1961) and a-1-antitrypsin (Kurachi et al., 1981; Bollen et al., 1983) peptides are aligned, respectively. Many of these differences are non-conservative in nature. For example aa residues 8 and 83 are Leu and Pro in baboon and Arg and Ala in man (Fig. 3). Despite the many aa differences, the hydropathy profiles (Kyte and Doolittle, 1982) of the baboon and human BCG peptides are virtually identical (Fig. 4). These profiles illustrate that the two most hydrophobic regions of the hormone (apart from the leader sequence) are localised approximately between aa residues 23 and 57 and residues 75 and 93. The most hydrophilic region covers the C-terminal portion of the peptide from about Cys residue 93 to about Gly 139. One particular aa difference between the peptides is noteworthy. It has been suggested that an Ala codon instead of Asp at aa position 117 in the human peptide, correlates with nonexpression in the human placenta (Talmadge et al., 1984b). This is clearly not the case in baboon because each of the baboon BCG cDNAs sequenced contain an Ala codon at this position. (e) Evolution of /KG genes
The pituitary glycoprotein hormones are synthesized in a wide range of species, whereas placental CG synthesis appears restricted to certain mammals (Canfield et al., 1978; Pierce and Parsons, 1981). Hence PCG is believed to be the most recently evolved member of the glycoprotein hormone /? subunit family. At least in man CG most closely resembles LH in structure (Dayhoff, 1976) and
VP1
36
Ila
Asn
Ala
Thr
Leu
Ala
Ala
I;I:I:
ATC
AAT
oc:c
ACI:
I:TF
C;IX
Ile
Cys
Ala
Gly
Tyr
TI>T
rjtX
1:~s At-g Fra TljC
C132
Val
Asn
Thr
Thr
ijTC
AAC
ACC
AI::I: ATI:
Lys
131~ Ala
I;C:I: I;AI~ TO
AAG
l>Al2 l?l~l~: Tl:iT l::l~:l: l>Tl> 1: G
Cys
Pro
Thr
Met
IXC
TAC: TOI:
l::lX
AN:
ATl_7 ATI> lZl3E l3TG t: t: 1:
Val
Val
Asn
Tyr
Arg
ASP Olu
Val
Arg
Pha
Glu
GTC
t3Trj
l:y!tt TtX
AAC
TAC
IZuC
l:AG
OTt2
IZcic
TTC:
GAG
Tyr Val
Ala Pro
Val
Ala
*
Ala Leu Lcu Pro Fro Val Pro rjln tzTt3 CCC CCC GTCi Cl~l~ CAG t: T 12
Lcu
Pro
C;ly
Cys
Pro
CTI=
CCT
GOC
TGC
CtX
I3 1 n Arg Cys
Ala
Leu
t:fiC
t;CA
CTC
TI>T
Arg Fro
Thr Mat
Cys
Ar’g
Pro
Val
Val
Lcu
Asn Asp
cily
Val
CCT t;c
tXtc.
GTG
GAI: A
Cys
Arg
Arg
Scr
TGC.
t;GC
CTjl:
AtX
Thr AtX
Fro t:tX
Val Met
Val
ATIS t:
GTC
!Ser Tt:T
Ser TtX
Asp
t::ys tily
t;Ar;
TOT
Arg Phe Asp Asp Pru Asn Lcu t3AT GAC CCC AAC: CTr, CG T
Leu
CGA
CTtZ
I>TI~ A
01n
Thr AIX
Gl y Ala Val l3tX t>
CiTtZ
:Ser
Ile
Arg
TCC
ATC
Ct>G
Leu
Ser
ASP Gin Ala CAG GtX A
tGTtIi GC:T t::TC AGC
01~
Fro
Lys
Asp
His
CCC
AAG
t3At:
CAC: XT
tGt37 tXiT
Fro Lru
Oly Glu
Cl73 1:
GAG G
Ala
0 !&r
Ser
Lys
Tt::C Tt:T
TW
TCA
AAG
Pra
11s Phe
Pro
Ser Ala
Asp rjly
Thr
CCA
WA
t:t3C
AtX
CTG
Fro
A
TOT
LWJ
TTtz t;
Set-
!&r
Cys
rjTT CCC TAC: Ci
Asp GAC 1:
Pro CCT
F’ro CCC
Fro CtX
Leu t;C:o TTC: CTI: A
Pro
14.3 rjln
)ew
lXt3
CAA
TAA
0 Arg
Tl>ll
t:
A
Pro Ssr Fro,Ser CCA At3T CCA TCC
Val
1Z:TG IZAG
Thr
0
Cys
T
AA
Thr CYS ACC TGT
IlC
GlY
Glu.
0
Let1
!%r AGC
Fr-a CCT T
AiX:TTC
A
Fig. 3. The nt and predicted aa sequences of baboon and human jCG subunits. The sequences of baboon jCG clone Cl (see Fig. 2) are aligned with those of human fiCG (Fiddes and Goodman, 1980). Only those positions which differ from baboon BCG are shown for the human sequence (nt differences below and aa replacement substitutions above the baboon sequence). Asterisks and letters 0 identify N-linked and O-linked glycosylation sites, respectively. The Ser residue at aa 158 is O-linked glycosylated in man (Canfield et al., 1978). The aa residue at this position in the baboon is Ala.
biological activity (Pierce and Parsons, 1981). This clone similarity is also apparent in the gene sequences of the respective fi subunits (Talmadge et al., 1984a). It is therefore likely that the jS33 gene originated by duplication of an ancestral BLH-like and gene, and that subsequent duplications rearrangements of the PCG gene were responsible
for the /?CG multigene family detected in humans and baboons. The evolutionary events from the point of fiCG$LH divergence are not clear. These events have resulted in a marked divergence of /KG-related genes between baboon and human. (In fact human PCG more closely resembles human /?LH (92.2% nt
168
It is significant
that a high proportion
of replace-
ment changes has occurred between human and baboon /?CG-genes; of 43 nt differences in the hormone
coding
region,
30 are replacement.
more many of the aa changes suggesting the
Hydropathy
B
Fig. 4. Hydropathy Doolittle
Sequences
were
analysed
(1982) using the computer
(A) Baboon
BCG; (B) human
human
and baboon
according programme
to Kyte
/XC and
of Dr. T. Kyne.
BCG.
and 85.2% aa homology) than baboon /?CG (90-91x nt and 82% aa homology; Table II). In contrast the sequences of /?CG-related genes within species (baboon or human) are very similar. These observations suggest that recombinational events, equal crossing-over or gene conversion events which may have resulted in the present BCG gene family, occurred much later than the primary /?CG//?LH duplication, and after the evolutionary divergence of baboon and man. However, this evolutionary course is unlikely because the j?CG gene duplication probably occurred soon after the separation of /3CG and /?LH genes, since the divergence rate of the introns from human PCG genes 5 and 6 is similar to that of PLH and fiCG introns (Talmadge et al., 1984a). Hence it is not clear how divergence of /?CG genes proceeded between species while maintaining sequence conservation within species. It is possible that gene conversion, which can operate to maintain homogeneity within a gene family (Slightom et al., 1980) has been involved in conserving j?CG sequences within species. However, such a conversion process has excluded the PLH gene, despite the close physical linkage of /?LH and PCG-like genes.
sequence
of BCG
explanations
First,
CG
may be under less selective pressure
than
hormonal
possible.
species.
Several
other
are
between
functions most
plot of aligned
that there is not a strict need to conserve
peptide
receptor
peptides.
Further-
are nonconservative,
activities.
may be capable
Second,
of responding
the CG to hetero-
geneous CG-related peptides, thus allowing the evolution of diverse CG-like peptides. The likelihood of this suggestion is supported by the observation that LH is capable of exerting CG-like activities (Pierce and Parsons, 1981) despite the high degree of sequence divergence between human /?LH and j?CG peptides (Table II). Alternatively selective pressure may act on the interaction between the CG peptide and its receptor rather than the flCG sequence alone. Divergence of BCG sequences between species would then be permitted if the BCG sequence and its receptor evolved congruently.
ACKNOWLEDGEMENTS
We thank Dr. T. Kuehl (San Antonio, TX) and Dr. V. Stevens (Ohio State University, Columbus, OH) for providing baboon placentae, and Dr. J. Fiddes for allowing the use of the human /?CG cDNA clone. We are grateful for the excellent technical assistance of Vicki Hammond and Lucy Duncan, and to Dr. Tony Kyne for use of computer programmes. This work was supported in part by the Special Programme for Research in Human Reproduction, World Health Organisation, and by the National Health and Medical Research Council of Australia.
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