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Rat aldolaseA messenger RNA: the nucleotide sequence and multiple mRNA species with different 5′-terminal regions
Gene. 39 (1985) 17-24
17
Elsevicr GENE
1407
Rat aldolaseA messenger RNA: the nucleotide sequence and multiple mRNA species with different 5’ -terminal regions (Recombinant
DNA;
cDNA
clones;
isozyme;
primer extension;
skeletal muscle)
Keiichiro Joh, Tsunehiro Mukai, Hitomi Yatsuki, and Katsuji Hori* Department
of Biochemistry,
(Received
April Sth, 1985)
(Revision
received
(Accepted
Saga Medical
School, Nabeshima,
Saga
840-01
[JapanJ Tel. (0952)
31-651 I
July 2nd. 1985)
July 3rd, 1985)
SUMMARY
The nucleotide sequence of aldolase clones and a cDNA synthesized
A mRNA in rat skeletal muscle was determined by primer extension. The sequence is composed
cDNA
using recombinant of 1343 nucleotides
(nt) except for the poly(A) tail. Based on the sequence analysis we have deduced an open reading frame with 363 amino acids (aa) (A4, 39 134). The sequence suggests several nt polymorphisms in the mRNA population, one of which causes an aa change. The determined sequence of rat aldolase A mRNA was compared with the published ones of rabbit aldolase A or rat aldolase B mRNAs. The homology between rat and rabbit aldolase A mRNA sequences is greater than that between rat aldolase A and B mRNA sequences. Multiple aldolase A mRNAs having different M,.s were detected in the various tissues, and appeared to be expressed in a tissue-specific manner. Further analysis suggests that differences in mRNA length are due to differences in the 5 ’ -noncoding terminal region.
INTRODUCTION It is well known that the multiple molecular of enzyme, “isozyme” (Markert and Moller,
* To whom
correspondence
and reprint
requests
forms 1959),
should
be
addressed. Abbreviations: cneglycol Hepes, kilobases
EGTA, ethyl-
ether)-N,A’flfl’-tetraacetic
acid;
4-(2-hydroxyethyl)-I-piperazineethanesulfonic or 1000 bp; nt, nucleotide(s);
poly(A) + RNA, sulfate;
aa, amino acid(s); bp, base pair(s);
bi@aminoethyl
polyadenylated
RNA;
acid; kb,
PA, polyacrylamide; SDS,
sodium
SSC, 0.15 M NaCI, 0.015 M Na. citrate,
0378-l 119~85.‘$03.30 0
1985 Elsevicr
Science
dodecyl
pH 7-8.
Publishers
exhibit tissue- or cell-specific patterns. That is,the isozyme patterns are different in different tissues and characteristic for the stages of differentiation in each tissue. Fructose 1,6-diphosphate aldolase (EC 4.1.2.13) is a glycolytic enzyme that catalyzes reversibly cleavage of fructose 1,6-diphosphate to glyceraldehyde 3-phosphate and dihydroxyacetone phosphate. Three isozymic forms of the aldolase have been reported in vertebrates (Horecker et al., 1972): aldolase A (muscle type), aldolase B (liver type), and aldolase C (brain type). The isozymes are different in their catalytic, electrophoretic, and antigenic properties and have been studied extensively with respect
IX
to the tissue
distribution
development
and
1972; Lebherz Because
and the changes
carcinogenesis
and Rutter,
of their
during
(Horecker
et al.,
1969).
characteristic
expressions,
it
alcohol (24 : 1) followed by LiCl
chloroform-isoamyl
precipitation, as usual. The poly(A) + RNA was isolated by oligo(dT) cellulose chromatography. Enrich-
seems that rat aldolase isozymes are an ideal material
ment of aldolase A mRNA successive centrifugations
for studying
a regulatory
gradients
sion during
development,
cinogenesis.
Furthermore,
mechanism
of gene expres-
differentiation the aldolase
offer a useful evolutionary
and carisozyme
will
model for understanding
the process
by which closely related genes and their
regulatory
mechanisms
have
diverged.
For
types in a species and genes of same type
in different
species.
cDNA clones and its nucleotide sequences have been reported for rat aldolase B (Tsutsumi et al., 1984a), rabbit aldolase A (Tolan et al., 1984) and human aldolase B (Rottmann et al., 1984; Paolella et al., 1984) mRNAs. Here, we describe the cloning and characterization of cDNA for aldolase A mRNA from rat skeletal muscle and also describe an analysis of the mRNAs with a distinct molecular size from the various tissues.
MATERIALS
AND MEI’HODS
(a) Materials Avian myeloblastosis virus reverse transcriptase was purchased from Life Science Inc. and nuclease Sl was from Boehringer Mannheim. Restriction enzymes and other enzymes were from Bethesda Research Laboratories Ltd., New England Biolabs, or Takara Shuzo Co., Ltd. Radioisotope-labeled compounds were obtained from Amersham. (b) Purification
rev./min 26°C
w/v, sucrose in 807” formamide,
pH 7.6 and 3 mM EDTA)
in a Beckman if necessary.
estimated
by two density at 37000
SW40 Ti rotor for 48 h at
The extent of enrichment
to be 3-4 fold by in vitro translation
was assay.
these
purposes, it is necessary to clarify the structural relationship of the relevant genes, that is, genes of different
(5-20%,
3 mM Hepes,
was performed on sucrose
(c) Construction Construction
and isolation of cDNA clones of cDNA
clones
using
a pBR322
vector and colony hybridization were performed as described previously (Tsutsumi et al., 1984a) with slight modifications. Depending upon the probe DNA used, one of two conditions with different stringency were chosen for the hybridization experiments as follows. Hybridization was carried out in a solution containing 1 x Denhardt’s solution (Denhardt, 1966), 50 mM Na. phosphate, pH 6.5, 200 pg/ml denatured salmon sperm DNA, 0.1% SDS and 6 x SSC at 55°C for aldolase B cDNA as a probe or in the same solution except for 4 x SSC at 65’ C for aldolase A cDNA as a probe. After hybridization, the filter was rinsed with 2 x SSC, 0.1 y0 SDS at room temperature and then washed twice with the same solution at 42’ C for B probe or 65 ’ C for A probe. (d) Primer extension The DNA fragment and poly(A)+ RNA were hybridized as described with some modifications (Maniatis et al., 1982). The hybrids were used to synthesize cDNA with reverse transcriptase as described (Tsutsumi et al., 1984a).
of poly(A)+RNA (e) Cleavage of mRNA with RNase H
Skeletal muscle of male Wistar rats was pulverized in a Waring blender filled with liquid nitrogen. The powder was suspended at 1 g/20 ml in 50 mM Tris . HCI buffer, pH 9.0, containing 0.3 M KCl, 10 mM MgC12, 5 mM EGTA, and 1 y0 SDS and mixed with an equal volume of phenol-chloroform-isoamyl alcohol (25 : 24 : 1 v/v), and the total RNA was extracted. The RNA was further extracted with phenol-chloroform-isoamyl alcohol and then with
Poly(A) + RNA and cDNA were hybridized as in section d. The resulting hybrid was digested with RNase H at 37°C for 30 min in 50 ~1 of 10 mM Tris HCl pH 7.6, 0.13 M NH,Cl, 10 mM Mg acetate, 5% sucrose and 2 units of RNase H (P.L. Biochemicals). After phenol extraction and ethanol precipitation the digests were analyzed by blothybridization using an appropriate 5’ or 3’ probe.
19
(f) Nucleotide Labeling
sequencing
and sequencing
of DNA by the method
of Maxam and Gilbert was performed according to a protocol (Maxam and Gilbert, 1980; Maniatis et al., 1982). For DNA chain terminator cloning
sequencing
method,
vector.
Sequencing
scribed (Messing,
M13mp8
by the dideoxy was used as a
was performed
as de-
1983) with some modifications.
Fig. 1. Restriction quencing RESULTS
maps
strategy.
of rat
Aldolase
shown as a solid bar (coding
(a) Aldolase A cDNA clones from rat skeletal muscle poly(A) + RNA
body method and electrophoresis on a SDS-PA gel (not shown). A possible aa sequence deduced from the nt sequence of one of the clones, pRAAM 1 (Fig. l), was found to be highly homologous to that of rabbit aldolase A reported by Lai et al. (1974). Therefore, we concluded that pRAAM1 was a rat aldolase A cDNA clone. Two clones, pRAAM40 and 83, were obtained by colony hybridization using pRAAM1 as a probe (Fig. 1). Their inserts were 1.2 kb long excluding the poly(A) sequence and covered 90% of the mRNA. The third clone, pRAAM103, whose cDNA insert was 0.55 kb long and covered
73% (48 nt) of the
5’-noncoding region (66 nt) and part of the coding region of the mRNA, was obtained by primer extension (Fig. 1). (b) Nucleotide
sequence of aldolase A mRNA
Most of the nt sequence of aldolase A mRNA in rat skeletal muscle was determined by sequencing
A cDNAs
and
of rat skeletal
se-
muscle is
region) and open bars (noncoding
regions)
at the top. The cDNA
positions
relative
to the mRNA.
inserts
are depicted
The restriction
in the
sites indicated
are: PslI (Ps), Pvull (Pv), Hinfl (H), TuqI (T) and Hue111 (7). of Hue111 sites in the pRAAM40
The mapping
been done yet. The sequencing
Poly(A) +RNA from rat skeletal muscle was enriched for aldolase A mRNA and used to construct cDNA clones as described in MATERIALS AND METHODS, sections b and c, respectively. The cDNA clones were screened by colony hybridization using rat aldolase B cDNA (pRAB3031; Tsutsumi et al., 1984a) as a probe at a low stringency. Several hybridization-positive clones were obtained and identified as an aldolase A cDNA clone by hybrid selection and translation experiment as described (Maniatis et al., 1982) followed by the double-anti-
aldolase
A mRNA
arrows.
The cDNA
fragment)
and
pRAAM103 pRAAM83 box and
fragments
probe
(see
arrow
DNA (ZzP-labeled
under
fragment)
section
as a filled and a hatched broken
insert
is indicated
used as a primer
(PsrI-HinfI
RMIJLTS,
a)
(Hid-HaelI for
are
cloning
shown
box, respectively.
pRAAM103
has not
by horizontal
indicate
portion
synthesis,
respectively.
of the mRNA
and the direction
This DNA fragment
of
under An open
a primer
at the 5’..4luI end) used for sequencing
5’-terminal experiment
strategy
ofthe
of cDNA
was also used for the
showsn in Fig. 6.
the cDNA inserts of pRAAM1, 83 and 103 (Fig. 1). To determine the nt sequence corresponding to the 5’ terminus of the mRNA, which appears to be missing in pRAAM103, a cDNA was synthesized using the primer shown in Fig. 1 and sequenced. Fig. 2 shows the nt sequence of mRNA for rat skeletal muscle aldolase A and the aa sequence deduced from the nt sequence. The mRNA has a chain length of 1343 nt except for the poly(A) tail and encodes 363 aa for aldolase A. Several microheterogeneities were observed among the cDNA inserts of pRAAM40, 83 and 103 in their restriction sites and nt sequences, as shown in Figs. 1 and 2. The variation in the codon at position 90 causes an aa change, GCC (pRAAM83) for alanine and GGC (pRAAM103) for glycine. There is no discrepancy between pRAAM1 and 83 so far as determined. (c) Comparison of rat aldolase A with rabbit aldolase A and rat aldolase B The aa sequence of rat skeletal muscle aldolase A deduced from the nt sequence of the mRNA is in
ala GCC
Glu GAA
Gly GGC
Ala GCA
Ala GCU
Gin CAG
Gly GGA
Val GUG
Cys UGU
Met Val GUG
Gly GGG
Glu GAA
Gly GGU
Pro CCA
Tie AUU
Val GuU
Arg ccc
Ile AUC
Asp GAU
Leu CUG
Val Thr GIJC ACA
Asn AAU
Leu CUG
Leu CUC
Trp uGG
Thr ACU
Tie AUC
Gfy GGC
Gly GGC
Lys AAG
Ile AUC
Leu CUU
Thr ACA
His CAU
Asn AAU
Gln CAG
Gln CAG
Lys AAG
Rsn AAC
Arq CGU
Leu CUG
Asp GAC
Ala GCC
Tyr UAU
Ile Lys AIJIJAAG
Val GUG
Ile AUU
~I Asp GAC
Asn AAC
Cjy GGA
Ala Ser UCU
Cys UCU
Thr ACA
Lys AAG
Glu GAG
Lys AAG
Arq CGA
Leu CUG
AAG
UUG
Phe Ser ~~Ala
leu CUG
Ala GCC
Pro CCU
Thr KU
Ser AGC
Glu GAA
Gln CAG
Gly GGG
Gly GGC
Glu GAG
lie AUC
Lys AAG
Ala GCU
Cys AAG
Arg CGC
G!y GGC
Glu GAG
Ser Leu IJCU CUC
Glu GAG
Trp Ala IJGG GCC
Thr Val Pro GUC: KU
Thr XC
Val GUA
Ala GCC
I.ys Pro AAG CCA
Ala GCC
~Val GUC
Tyr UAU
Tyr UAC
P-.-1 Ala Ser GCC AGU
320 Leu Lys CIJG AAG
Ala GCA
Ala GCA
Leu CUG
290 Pro CCC
350 Ala GCC
Leu CUG
Fro CCC
Pro CCU
Met AUG
Gln CAG
Arg CGU
Val GUG
260
Asn AK
230 Pro CCC
Cys
200 Arg
-~ Lys UGC
Ala GCC
170 Val Leu GULJ CUG
CGC
Gly CGA
140 Asp GAU
Lys AAG
Val Pro GIJG Ccc
Gin CAG
Arq AGG
Gnc U~IJ Gee
Val GUA
Gly GGU
110 Lys AAG
Asp GAU
Leu
Asn AAU
Lys AAG
Val GUA
Leu Tyr CUG UAC (A)
Asn AAC
Gee
Thr ACA
80 His Glu CAC GAG
Glu GAG
Ala Pro GCIJ CCG
Asp
Glu GAG
50 Asn Thr AAC ACC
Glu GAG
Val GUA
Ala
Ile AUU
20 His Arg CAC CGA
Ala GCU
Leu Phe ClJIJUUC
Thr ACC
Ile AUC
AGCCCACUGCChAUAAACAGC~JAUUUAAGGGGnnAAnnnAAA----------
Ser AGU
Gly GGG
Asp GAC
Gly GGC
Gly GGG
Ser UCC
Glu GAG
Lys AAG
-Ser Lcu Ala CUC, GCU Gly GGC
30 Leu Ala CUG GCU
ala GCC
Thr KU
Gln CAA
240 Thr ACC
210 Ala GCA
360 Asn AAC
330 Arg CGA
Val 1l.c Lys AUC AAG
His CAU
Ala GCC
Lys AAG
Pro CCC
Ala GCU
Ile AUU
Gly GGA
Ala GCC
363 Tyr UAC
Lcu Ala ClJG GCC
Arg CGA
Gly GGG
tcr UAA
Asn AAC
Ala WC
GLn CAG
Glu GAG
Glu GAG
Leu CUG
Leu CUC
His CAC
Glu GAA
Ser UCG
Gly GGG
Ser KC
Val GUG
Ile AUU
Ser UCU
Glu GAG
Gln CAA
Ala GCU
Ala GCA
Ile Ala AU11 GCC
Asp GAC
Ala Cys GCrJ UGU
ala GCC
GAA
Glu
Glu GAA
Ser AGU
Pro CCU
Pro ccc
Asp GAC
Lys RAG
Arq CGU
Ser AGC
Pro CCG
340 Gly GGA
310 Leu CUA
280 Ser KC
250 Met AUG
220 His CAU
Glu GAG
Gly GGCJ
Cys LIGC
Arq CGC
Lys AAG
Lys AAG
Lys AAG
Ile AUC
Ala GCA
Ile Val GUC
{Le~clld o*ipage21,
Tyr []A('
Ala WII
Asn AAC
Thr AC(
Tyr UA[I
Pro CCIJ
Leu Ala CIIC GCC
Ser UCU
Gly GGU
190 Ile Leu AUU CUC
130 Leu CUG 160 Ala Ser ucc
100 Lys AAG
70 Asn Pro AAU CCC
40 Ala Lys GCC AAG
10 Glu Gln GAG CAG
CChGAGCUGAlJClJAAGGCUGCUCCAUCGACA
Ser AGC
Thr ACU
Ceu CUG
Ile AUC
~Asp GAC
Gly GGA
L,eu Thr CUG ACC
Val Glu G[JG GAG
His CAU
Gly GGG
Val GUU
Asp GAU
Thr ACU
Ala GCA
T,eu Gln CIIG CAG
Ser AGU
Tyr ~- His 1,~s Phe Ser Asn AAA lJUU IJCC AAU
Tyr Gly [JAI1GGC
Ser UCU
Gln CAG
Ala Val Tyr GClJ GIJC UAC
Ile AUU
Val GUA
Thr ACU
180 Asn Gly AAlJ GGC
300 Ser UCC
Str UCU
Thr ACU
Ser UCC
--~~~ Phc Pro Gin IJUC CCC CAA
Leu CUG
Glu GAG
Pro CCA
Ile tily Glu RUIJ GGG GAG
Thr ACC
Pro CCC
Leu CUG
Asp GAC
His Tyr UAC
150 Val T,eu Lys GIJC CUA AAG
270 Phe Leu UIJC CUG
Cys UGC
Lcu CUC
Gln CAG
Cys mxi
Arg CGC
Ala GCA
1 Ser Pro 111s Pro CCC CAC CCA
60 _.__ Gln Leu CAA CUG 90 (Ala) Asp Gly Arg GAU GGC CGU (C) ~_~~ -120 Asn Gly Glu AAU GGC GAG
Ile AUC
Phe UUC
Thr AYU
Thr ACU
Ala GCU
Val GUA
Gln CAG
Arg CGC
Thr ACC
~.. Asp GAU
Phc Ilr lJUC AK
Tyr UAC
Ltu UUG
Val GUC
His CAU
Lys AAG
Cys UGC
Trp uGG
Gly GGA
~-Ala GCA
-Phe Tyr UlJC UAC
Lys AAG
NNNNGCIJGCUGACCAGGCUCIJGCGGCUUCllIJUCAC!JGCACCAc:AGcAAAGCGCUGCCACCGGCACC
Met AUG
21
agreement
with that of rabbit
from the mRNA for
12 aa,
homology
M
aldolase A deduced
indicating (97%).
remarkably
There
high
sequence
S
H
M
28S+
is also a high sequence
homology between the noncoding regions, especially between the 3’ regions, although they are considerably
B
sequence (Tolan et al., 1984) except
23S-,
different in length (Fig. 3). This size differ-
ence seems to be caused sequence and/or seen in Fig. 3.
by insertions
deletions
in the rabbit
in the rat sequence,
18s-, 16S+
as
Comparison of the sequence of rat aldolase A with those of rat aldolase B (Tsutsumi et al., 1984a) shows that many aa substitutions occurred between these enzymes (Fig. 2). The homology between the aa sequences was 70%. The 3’-noncoding regions of the mRNAs for rat aldolases A and B are quite different in length (182 nt for aldolase A and 384 nt for aldolase B) and have no significant sequence
Fig. 4. RNA various cellulose agarose
filters
of aldolaseA
Poly(A)‘RNAs
after
mRNAs
expressed
were blotted
electrophoresis
gels (Maniatis
translated
homology. On the other hand, the 5’-noncoding regions are similar in length; yet no significant sequence homology was observed.
blot-analysis
rat tissues.
on
pRAAM83
[32P]cDNA
insert
pg), brain (B, 5 pg), heart
(H, 5 pg) and spleen (S,I5pg).M,
region
: NNNNGCUGCUGACCAGGCUCUGCGGCUUCUUUCACUGCACCAC AGGAAAGCGCUGCCACCGGCACC . . . _.. . .._. . . . . . . ..-. .._..._e... ..-....--.. ACUACUGCUGACCAG CUCUGCGGCUCCUACAGCCUCGCCGCAAGGAACU UGCUACCAGCACC Rabbit:
AUG---
Rat
3.noncoding : --UAA --UAA
Rabbit:
.._
..
.-..._..
..
..
.-
AUG---
region
CCAGAGCUGAUCUAAGGCUGCUCCAUCGACACUCCAGGCCCCUGCCU
.
(Mukai
muscle (M, 0.25
markersarerRNAs.
5 noncoding
Rat
?a
with a nick-
as described
RNAs are from skeletal
in
nitro-
formaldehyde-l
et al., 1982) and hybridized
et al., 1984). Poly(A)+
onto
..--.._--..
ACCCA
. . ._
.. ..
GCGGAGGUGUUCUAAGGCCGCCCCCUCAACACUCCACUCCAGGCUCCAGCACCGGCCCCCCUACACACACA
CUUGCUAUUGAAGAGGG GCCUU CAGGCUC UUUCCCAUCACUCUUGCUGCCCUCGUG . . . . . .-........ . . .. .-...m _..._.. _..._..._ _...__.. CUCGCUCUUGAAGAGGGAGCCUUCUUGGGGGUUCCAGGCUGUGUUUCCCACCACUCUUGCCUCCCUCGUGACUUUGG
UGUGCAGUGUUGUCUGUGAAUGCUAAAUCUGCCAUC CCUUCCAGCCCACUGCCAAUAAACAGCUAUUUAAGGGG . ... . . ..-...-. . . . . - . . . . . . . . _.._..._....._..._..._............._ UGUGUGGUAUUGUCUGUGUACGCUAUAACU CCAUCACUUUCCAGCCCACUGCCAAUAAACAGCUAUUUAAGGGGG Fig. 3. Homologous and rabbit
mRNAs
sequences
and 221 nt, respectively.
aa sequence indicate
of aldolase
ofthe pRAAM83
A mRNA
indicate
aldolase
The 3’ sequences identical
from rat skeletal
in the mRNA sequence of the primer
region is also underlined.
mRNAs
aldolase
A are shown
previously
are from the pRAAM103
used for the primer extension
was determined
are unknown
and 103 inserts are shown. Those nt in parentheses
the HhaI site, which is a 3’ terminus
The 5’-noncoding
AAA--
sequences
of the rat
are composed
of 182
nt.
muscle. The sequence
aa in rabbit B reported
A mRNAs.
of the rat and rabbit
The initial four nt of the 5’ terminus
from those of rat aldolase
insert; the nt at the same positions signal in the 3’-noncoding
of rat and rabbit
A is also shown. The different
those that are different
the sequences
two sequences
and 103, and by primer extension. of rat aldolase
regions
of 66 and 62 nt, respectively.
Dots between
Fig. 2. Nucleotide sequence pRAAM83
of the noncoding
are composed
AAAA--
(Tsutsumi
from the cDNA
and are indicated
inserts
of
by N. The deduced
above the rat sequence.
Bars on the aa
et al., 1984a). Two discrepancies
between
under codons No. 83 and 90 are from the pRAAM83 insert. GCGC experiment
in the 5’.noncoding
described
region indicates
in Fig. 6. The polyadenylation
22
(d) Aldolase A mRNAs regions
with different 5’-terminal
reported
(Mukai
for the mRNA Aldolase
A mRNAs
sues were analyzed
expressed
smaller
in various
by blot-hybridization
The aldolase A mRNA slightly
than
(Fig. 4).
from skeletal
those
from
rat tis-
muscle
other
was
tissues
as
A cDNA
3'
Tsutsumi
et al.,
to be approx.
1.55 kb
from skeletal muscle and 1.60- 1.65
kb for those from other tissues. We performed
an experiment
analogous
to that
described by Hagenbtichle et al. (1981) to locate the sequence that is responsible for the size difference. The aldolase A mRNA was hybridized with the
portion
mRNA
by digestion
RNA fragments
1
RNaseH
ization
with RNase
H. The 5 ’ and 3 ’
were then analyzed
with appropriate
by blot-hybrid-
5’- and 3’-specific
probes
prepared from the cDNA clones (Fig. 5). A size difference of approx. 50-100 nt was detected with the mRNA fragments bearing the 5’ end, but not with the 3’ fragments. For further analysis of the 5’
B a 1
1984;
220-bp HinfI fragment of pRAAM83 and cleaved into two fragments by removing the hybridized
fragment
w
5’
et al.,
1984b). The size was estimated
portion of the mRNA, cDNA was synthesized on the mRNA by primer extension using the Hhal-A/u1 cDNA fragment of pRAAM103 (Fig. 1) as a primer
b
and analyzed on a urea-PA gel (Fig. 6). Three major cDNA products, designated as I, II and III, whose sizes were estimated to be 110, 160 and 205 nt, respectively, were observed in the mRNAs from different tissues. The major cDNA product of the mRNA from skeletal muscle was cDNA I, whereas those of mRNAs from other tissues were cDNA II and III. The size difference between cDNA I and II or III was approx. 50-100 nt, which corresponded
12
2
-
1630
-
520
-
M
-
H
B
S
L - 1631
-
Fig. 5. Location (A) Schematic molecules
of size
220
in aldolase
of the procedure
into 5’ and 3’ fragments
fragment
-
difference
representation
J510 394 - 344 - 290
with RNase
used is the 220.bp ffinfl fragment
insert (see Fig. 1). (B) Blot-hybridization ments of aldolasc and
ascites
express heart,
a longer aldolase mRNAs
gels and blotted hybridized
onto GeenScreen
species
(bp) are Hbzfl-digested
(lane 1)
is known
on glyoxal,‘2”,, filters (NEN).
pBR322.
Fig. 6. Analysis
of cDNA
results).
minal region ofaldolase
agarose
DNA
Filters
ofpRAAM
is shown
products
synthesized
on the 5’-tcr-
A mRNA by primer extension.
in Fig.
I. Poly(A)’
RNAa
are from
A primer skeletal
were
muscle (M, 2 keg), heart muscle (H. 4 pg), brain (B, 4 pg), spleen
103
(S, 15 llg), and adult liver (L, IO pg). 0.08 pmol of the primer
probe or (b) 460-bp P.ul fragment
insert as a 3’-specific
primeL
to
like those of brain,
with either of(a) 1X0-bp PstI fragment cDNA
muscle
et al., 1984 and unpublished
were electrophorcsed
cDNA
of the 5’ and 3’ frag-
(lane 2), which
A mRNA
insert as a 5’-specific
of pRAAM83
H. The cDNA
of pRAAM83
from rat skeletal
AH60C
and spleen (Mukai
Cleaved
cDNA
A mRNAs
hepatoma
A mRNAs.
to cleave mRNA
probe. Size markers
DNA
was hybridized
products
with each
were subjected
gels (Maxam
and Gilbert.
poly(A)
to elcctrophoresis
’ RNA. The cDNA on 50’1,J urea:X”,, PA
1980). Size markers
are as in Fig. 5.
23
to the differences between seen in Fig. 4 and 5.
the sizes of the mRNAs
between
cDNA
I (110 nt) and cDNAs
and 205 nt) is in agreement between
aldolase
A mRNAs
II, III (160
with the differences in skeletal muscle and
other tissues observed in Figs. 4 and 5. If this is the case, the difference between two aldolase A mRNA DISCUSSION
species is located
in the region upstream
from the
HhaI
site (3’ terminus of the primer DNA) in the 5’-noncoding sequence. When aldolase A mRNAs
We have isolated several cDNA clones corresponding to a nearly entire region of aldolase A mRNA from rat skeletal muscle. We observed that
in skeletal muscle and brain were blot-hybridized with the cDNA fragment upstream of the HhaI site
there were several microheterogeneities in the nt sequences among the cDNA clones analyzed (Fig.
in the 5’-noncoding sequence of pRAAM 103 insert, a hybridization band was observed in skeletal muscle
2). It is most likely that these heterogeneities
poly(A) + RNA but not in brain poly(A) + RNA (not
resulted
from a heterogeneous mRNA population arising from allelic variation, since the mRNA used for cDNA cloning was prepared from many rat individuals. The observed aa change (Fig. 2) does not affect the net charge of the protein and probably not the enzymatic properties. Such allelic variation or polymorphism may be ubiquitous in eukaryotic genomes, since electrophoretic variants which arose from allelic variations have been reported for many enzymes or proteins of vertebrates, including man, and insects such as Drosophila (Johnson, 1977; Koehn and Eanes, 1979; Kreitman, 1983). Aldolase A mRNA in skeletal muscle is slightly shorter than those in other tissues (Fig. 4). This difference is mainly in the 5’ portion of the mRNA, not merely in the length of the poly(A) tail because, as seen in Fig. 5, only 5’ fragments of the mRNAs show a size difference which agrees well with the difference between the intact mRNAs observed in Fig. 4. It is therefore concluded that at least two species of aldolase A mRNA, whose 5’ portions are of different lengths, are expressed in a tissue-specific manner; i.e., the shorter one is in skeletal muscle and the longer one is in other tissues. Furthermore, three cDNA products with different lengths were produced by primer extension (Fig. 6). Although we cannot exclude the possibility that these cDNA products were produced by multiple premature terminations of cDNA synthesis on an aldolase A mRNA, it is more likely that cDNA I was synthesized on the shorter mRNA abundant in skeletal muscle and cDNA II and III were on the longer one abundant in other tissues by the following reasons. First, cDNA I is a major product only with mRNA from skeletal muscle and a very minor one with mRNAs from other tissues. Second, the size difference
shown). This observation suggests that two aldolase A mRNA species differ not only in length but in the nt sequence of the 5’-noncoding region. Comparing the rat and rabbit aldolase A mRNAs, highly homologous sequences were found in both the 5’- and 3’-noncoding regions, as shown in Fig. 3. In contrast, no distinct homologous sequence was found in either noncoding region between rat aldolase A and B mRNAs. The divergence of aldolase A and B genes should have occurred before the appearance of vertebrates, i.e., prior to the divergence of the rat and rabbit aldolase A genes, because these isozymes have been found in all the vertebrates so far examined (Lebherz and Rutter, 1969). Therefore, the presence or absence of homologous sequences in the noncoding regions may be explained by the difference in time after divergence ofthe genes. Alternatively, it may also be possible that the common sequences in the noncoding regions of the aldolase A mRNAs carries a regulatory function specific for aldolase A gene expression.
ACKNOWLEDGEMENTS
an
We thank Dr. M. Ikehara for generously providing antibody against rat aldolase A and Dr. Y.
Nabeshima for valuable suggestions about the preparation of RNA from skeletal muscle. This investigation was supported in part by a Grant-in-aid for Scientific Research from the Ministry of Education, Science and Culture of Japan.
24
Markert.
REFERENCES
C.L.
Tissues,
and
Nat]. Acad. Denhardt,
D.T.: A membrane-filter
of complementary
technique
DNA. Biochem.
Maxam,
for the detection
Biophys.
P.K.
r-amylase Nature
Young,
R.A.:
Mouse
and
salivary
mRNAs differ only in 5’ non-translated
B.L., Tsolas,
structural
Rattazzi,
M.C.,
in Boyer,
Press, New York,
constraints
Isozymes,
Vol. 2. Liss, New York,
and
Kreitman,
variation
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and
polymor-
variation,
Whitt,
G.S.
in
structure,
G.S. (Eds.),
polymorphism
Proc.
end-labeled
DNA
Methods
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for cloning.
in Rattazzi.
M.C.,
Isozymes,
Vol. 3.
at the alcohol dehydroNature
Methods
Enzymol.
H., Sakakibara,
and
Res. Commun.
ascites
G., Santamaria,
cDNA
M., Arai, Y., and
of rat aldolase
A mRNA in the
hepatoma
cells.
Biochem.
119 (1984) 575-581. R., Izzo, P., Costanzo,
and nucleotide
coding for aldolase
P. and Salva-
sequence
B from human
of a full-length liver. Nucl. Acids
W.H.,
acid sequence
cDNA
and genomic
D.R. and
Penhoet,
E.E.: Complete
for human
aldolase
B derived
clones.
Proc. Natl. Acad.
from
Sci. USA 81
(I 984) 2738-2742. D.R.,
Penhoet,
304 (1983)
Tolan,
amino
Amsden,
A.B., Putney,
E.E.: The complete
muscle aldolase
S.D.,
nucleotide
A messenger
Urdea,
M.S. and
sequence
for rabbit
RNA. J. Biol. Chcm. 259 (1984)
1127-I 131. D.: Amino
and the structure
acid sequence
of
in biological
offructose
systems.
Fritsch. Harbor,
sequence
8
Tsutsumi,
E.F. and Sambrook,
J.: Molecular
Cold Spring Harbor
NY, 1982.
Cloning.
Laboratory,
J. Biochem.
aldolase 142 (1084b)
M., Daimon,
K. and Ishikawa, B messenger
K.: RNA.
14572-14575.
Numazaki, A mRNA 161-164.
Cold Communicated
R., Mori,
H., Hori,
of rat liver aldolase
R., Tsutsumi,K.,
Two different
Manual.
T.. Tsutsumi,
T., Yatsuki,
J. Biol. Chem. 259 (1984a)
diphos-
Biochemistry
(1969) 109-121. A Laboratory
K., Mukai.
Nucleotide
H.G. and Rutter, W.J.: Distribution variants
Tsutsumi,
M., Tanaka,
of the active center.
183 (1974) 1204-1206.
phate aldolase
Spring
Biophys.
Tolan,
melunogusier.
N. and Chang,
rabbit muscle aldolase
Maniatis,T.,
muscle
Rottmann,
polypcptidc
412-417. Lai, C.Y., Nakai,
Lebherz,
of enzymes:
patterns.
Res. 12 (1984) 7401-7410.
(Eds.),
1979, pp. 185-211.
locus of Drosophila
Science
skeletal
tore, F.: Isolation
1Y77, pp. I-19.
of enzymes,
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M.: Nucleotide
genasc
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Koehn, R.K. and Eanes, W.F.: Molecular Scandahos,
.I.: New Ml3 vectors
Paolella, allozymes,
phisms:
Liss, New York,
cleavages.
Hori, K.: Different expression
Vol. 7. Academic
Isozymes,
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W.: Sequencing
chemical
Mukai, T., Joh, K., Miyahara,
1972, pp. 213-258. G.B.:
forms
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A.M. and Gilbert,
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U., Bovey, R., Wellauer, liver
289 (1981) 643-646.
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with base-specific
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ontogenetic,
by H. Yoshikawa
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K.:
species in rat tissues.
Eur.
17
Elsevicr GENE
1407
Rat aldolaseA messenger RNA: the nucleotide sequence and multiple mRNA species with different 5’ -terminal regions (Recombinant
DNA;
cDNA
clones;
isozyme;
primer extension;
skeletal muscle)
Keiichiro Joh, Tsunehiro Mukai, Hitomi Yatsuki, and Katsuji Hori* Department
of Biochemistry,
(Received
April Sth, 1985)
(Revision
received
(Accepted
Saga Medical
School, Nabeshima,
Saga
840-01
[JapanJ Tel. (0952)
31-651 I
July 2nd. 1985)
July 3rd, 1985)
SUMMARY
The nucleotide sequence of aldolase clones and a cDNA synthesized
A mRNA in rat skeletal muscle was determined by primer extension. The sequence is composed
cDNA
using recombinant of 1343 nucleotides
(nt) except for the poly(A) tail. Based on the sequence analysis we have deduced an open reading frame with 363 amino acids (aa) (A4, 39 134). The sequence suggests several nt polymorphisms in the mRNA population, one of which causes an aa change. The determined sequence of rat aldolase A mRNA was compared with the published ones of rabbit aldolase A or rat aldolase B mRNAs. The homology between rat and rabbit aldolase A mRNA sequences is greater than that between rat aldolase A and B mRNA sequences. Multiple aldolase A mRNAs having different M,.s were detected in the various tissues, and appeared to be expressed in a tissue-specific manner. Further analysis suggests that differences in mRNA length are due to differences in the 5 ’ -noncoding terminal region.
INTRODUCTION It is well known that the multiple molecular of enzyme, “isozyme” (Markert and Moller,
* To whom
correspondence
and reprint
requests
forms 1959),
should
be
addressed. Abbreviations: cneglycol Hepes, kilobases
EGTA, ethyl-
ether)-N,A’flfl’-tetraacetic
acid;
4-(2-hydroxyethyl)-I-piperazineethanesulfonic or 1000 bp; nt, nucleotide(s);
poly(A) + RNA, sulfate;
aa, amino acid(s); bp, base pair(s);
bi@aminoethyl
polyadenylated
RNA;
acid; kb,
PA, polyacrylamide; SDS,
sodium
SSC, 0.15 M NaCI, 0.015 M Na. citrate,
0378-l 119~85.‘$03.30 0
1985 Elsevicr
Science
dodecyl
pH 7-8.
Publishers
exhibit tissue- or cell-specific patterns. That is,the isozyme patterns are different in different tissues and characteristic for the stages of differentiation in each tissue. Fructose 1,6-diphosphate aldolase (EC 4.1.2.13) is a glycolytic enzyme that catalyzes reversibly cleavage of fructose 1,6-diphosphate to glyceraldehyde 3-phosphate and dihydroxyacetone phosphate. Three isozymic forms of the aldolase have been reported in vertebrates (Horecker et al., 1972): aldolase A (muscle type), aldolase B (liver type), and aldolase C (brain type). The isozymes are different in their catalytic, electrophoretic, and antigenic properties and have been studied extensively with respect
IX
to the tissue
distribution
development
and
1972; Lebherz Because
and the changes
carcinogenesis
and Rutter,
of their
during
(Horecker
et al.,
1969).
characteristic
expressions,
it
alcohol (24 : 1) followed by LiCl
chloroform-isoamyl
precipitation, as usual. The poly(A) + RNA was isolated by oligo(dT) cellulose chromatography. Enrich-
seems that rat aldolase isozymes are an ideal material
ment of aldolase A mRNA successive centrifugations
for studying
a regulatory
gradients
sion during
development,
cinogenesis.
Furthermore,
mechanism
of gene expres-
differentiation the aldolase
offer a useful evolutionary
and carisozyme
will
model for understanding
the process
by which closely related genes and their
regulatory
mechanisms
have
diverged.
For
types in a species and genes of same type
in different
species.
cDNA clones and its nucleotide sequences have been reported for rat aldolase B (Tsutsumi et al., 1984a), rabbit aldolase A (Tolan et al., 1984) and human aldolase B (Rottmann et al., 1984; Paolella et al., 1984) mRNAs. Here, we describe the cloning and characterization of cDNA for aldolase A mRNA from rat skeletal muscle and also describe an analysis of the mRNAs with a distinct molecular size from the various tissues.
MATERIALS
AND MEI’HODS
(a) Materials Avian myeloblastosis virus reverse transcriptase was purchased from Life Science Inc. and nuclease Sl was from Boehringer Mannheim. Restriction enzymes and other enzymes were from Bethesda Research Laboratories Ltd., New England Biolabs, or Takara Shuzo Co., Ltd. Radioisotope-labeled compounds were obtained from Amersham. (b) Purification
rev./min 26°C
w/v, sucrose in 807” formamide,
pH 7.6 and 3 mM EDTA)
in a Beckman if necessary.
estimated
by two density at 37000
SW40 Ti rotor for 48 h at
The extent of enrichment
to be 3-4 fold by in vitro translation
was assay.
these
purposes, it is necessary to clarify the structural relationship of the relevant genes, that is, genes of different
(5-20%,
3 mM Hepes,
was performed on sucrose
(c) Construction Construction
and isolation of cDNA clones of cDNA
clones
using
a pBR322
vector and colony hybridization were performed as described previously (Tsutsumi et al., 1984a) with slight modifications. Depending upon the probe DNA used, one of two conditions with different stringency were chosen for the hybridization experiments as follows. Hybridization was carried out in a solution containing 1 x Denhardt’s solution (Denhardt, 1966), 50 mM Na. phosphate, pH 6.5, 200 pg/ml denatured salmon sperm DNA, 0.1% SDS and 6 x SSC at 55°C for aldolase B cDNA as a probe or in the same solution except for 4 x SSC at 65’ C for aldolase A cDNA as a probe. After hybridization, the filter was rinsed with 2 x SSC, 0.1 y0 SDS at room temperature and then washed twice with the same solution at 42’ C for B probe or 65 ’ C for A probe. (d) Primer extension The DNA fragment and poly(A)+ RNA were hybridized as described with some modifications (Maniatis et al., 1982). The hybrids were used to synthesize cDNA with reverse transcriptase as described (Tsutsumi et al., 1984a).
of poly(A)+RNA (e) Cleavage of mRNA with RNase H
Skeletal muscle of male Wistar rats was pulverized in a Waring blender filled with liquid nitrogen. The powder was suspended at 1 g/20 ml in 50 mM Tris . HCI buffer, pH 9.0, containing 0.3 M KCl, 10 mM MgC12, 5 mM EGTA, and 1 y0 SDS and mixed with an equal volume of phenol-chloroform-isoamyl alcohol (25 : 24 : 1 v/v), and the total RNA was extracted. The RNA was further extracted with phenol-chloroform-isoamyl alcohol and then with
Poly(A) + RNA and cDNA were hybridized as in section d. The resulting hybrid was digested with RNase H at 37°C for 30 min in 50 ~1 of 10 mM Tris HCl pH 7.6, 0.13 M NH,Cl, 10 mM Mg acetate, 5% sucrose and 2 units of RNase H (P.L. Biochemicals). After phenol extraction and ethanol precipitation the digests were analyzed by blothybridization using an appropriate 5’ or 3’ probe.
19
(f) Nucleotide Labeling
sequencing
and sequencing
of DNA by the method
of Maxam and Gilbert was performed according to a protocol (Maxam and Gilbert, 1980; Maniatis et al., 1982). For DNA chain terminator cloning
sequencing
method,
vector.
Sequencing
scribed (Messing,
M13mp8
by the dideoxy was used as a
was performed
as de-
1983) with some modifications.
Fig. 1. Restriction quencing RESULTS
maps
strategy.
of rat
Aldolase
shown as a solid bar (coding
(a) Aldolase A cDNA clones from rat skeletal muscle poly(A) + RNA
body method and electrophoresis on a SDS-PA gel (not shown). A possible aa sequence deduced from the nt sequence of one of the clones, pRAAM 1 (Fig. l), was found to be highly homologous to that of rabbit aldolase A reported by Lai et al. (1974). Therefore, we concluded that pRAAM1 was a rat aldolase A cDNA clone. Two clones, pRAAM40 and 83, were obtained by colony hybridization using pRAAM1 as a probe (Fig. 1). Their inserts were 1.2 kb long excluding the poly(A) sequence and covered 90% of the mRNA. The third clone, pRAAM103, whose cDNA insert was 0.55 kb long and covered
73% (48 nt) of the
5’-noncoding region (66 nt) and part of the coding region of the mRNA, was obtained by primer extension (Fig. 1). (b) Nucleotide
sequence of aldolase A mRNA
Most of the nt sequence of aldolase A mRNA in rat skeletal muscle was determined by sequencing
A cDNAs
and
of rat skeletal
se-
muscle is
region) and open bars (noncoding
regions)
at the top. The cDNA
positions
relative
to the mRNA.
inserts
are depicted
The restriction
in the
sites indicated
are: PslI (Ps), Pvull (Pv), Hinfl (H), TuqI (T) and Hue111 (7). of Hue111 sites in the pRAAM40
The mapping
been done yet. The sequencing
Poly(A) +RNA from rat skeletal muscle was enriched for aldolase A mRNA and used to construct cDNA clones as described in MATERIALS AND METHODS, sections b and c, respectively. The cDNA clones were screened by colony hybridization using rat aldolase B cDNA (pRAB3031; Tsutsumi et al., 1984a) as a probe at a low stringency. Several hybridization-positive clones were obtained and identified as an aldolase A cDNA clone by hybrid selection and translation experiment as described (Maniatis et al., 1982) followed by the double-anti-
aldolase
A mRNA
arrows.
The cDNA
fragment)
and
pRAAM103 pRAAM83 box and
fragments
probe
(see
arrow
DNA (ZzP-labeled
under
fragment)
section
as a filled and a hatched broken
insert
is indicated
used as a primer
(PsrI-HinfI
RMIJLTS,
a)
(Hid-HaelI for
are
cloning
shown
box, respectively.
pRAAM103
has not
by horizontal
indicate
portion
synthesis,
respectively.
of the mRNA
and the direction
This DNA fragment
of
under An open
a primer
at the 5’..4luI end) used for sequencing
5’-terminal experiment
strategy
ofthe
of cDNA
was also used for the
showsn in Fig. 6.
the cDNA inserts of pRAAM1, 83 and 103 (Fig. 1). To determine the nt sequence corresponding to the 5’ terminus of the mRNA, which appears to be missing in pRAAM103, a cDNA was synthesized using the primer shown in Fig. 1 and sequenced. Fig. 2 shows the nt sequence of mRNA for rat skeletal muscle aldolase A and the aa sequence deduced from the nt sequence. The mRNA has a chain length of 1343 nt except for the poly(A) tail and encodes 363 aa for aldolase A. Several microheterogeneities were observed among the cDNA inserts of pRAAM40, 83 and 103 in their restriction sites and nt sequences, as shown in Figs. 1 and 2. The variation in the codon at position 90 causes an aa change, GCC (pRAAM83) for alanine and GGC (pRAAM103) for glycine. There is no discrepancy between pRAAM1 and 83 so far as determined. (c) Comparison of rat aldolase A with rabbit aldolase A and rat aldolase B The aa sequence of rat skeletal muscle aldolase A deduced from the nt sequence of the mRNA is in
ala GCC
Glu GAA
Gly GGC
Ala GCA
Ala GCU
Gin CAG
Gly GGA
Val GUG
Cys UGU
Met Val GUG
Gly GGG
Glu GAA
Gly GGU
Pro CCA
Tie AUU
Val GuU
Arg ccc
Ile AUC
Asp GAU
Leu CUG
Val Thr GIJC ACA
Asn AAU
Leu CUG
Leu CUC
Trp uGG
Thr ACU
Tie AUC
Gfy GGC
Gly GGC
Lys AAG
Ile AUC
Leu CUU
Thr ACA
His CAU
Asn AAU
Gln CAG
Gln CAG
Lys AAG
Rsn AAC
Arq CGU
Leu CUG
Asp GAC
Ala GCC
Tyr UAU
Ile Lys AIJIJAAG
Val GUG
Ile AUU
~I Asp GAC
Asn AAC
Cjy GGA
Ala Ser UCU
Cys UCU
Thr ACA
Lys AAG
Glu GAG
Lys AAG
Arq CGA
Leu CUG
AAG
UUG
Phe Ser ~~Ala
leu CUG
Ala GCC
Pro CCU
Thr KU
Ser AGC
Glu GAA
Gln CAG
Gly GGG
Gly GGC
Glu GAG
lie AUC
Lys AAG
Ala GCU
Cys AAG
Arg CGC
G!y GGC
Glu GAG
Ser Leu IJCU CUC
Glu GAG
Trp Ala IJGG GCC
Thr Val Pro GUC: KU
Thr XC
Val GUA
Ala GCC
I.ys Pro AAG CCA
Ala GCC
~Val GUC
Tyr UAU
Tyr UAC
P-.-1 Ala Ser GCC AGU
320 Leu Lys CIJG AAG
Ala GCA
Ala GCA
Leu CUG
290 Pro CCC
350 Ala GCC
Leu CUG
Fro CCC
Pro CCU
Met AUG
Gln CAG
Arg CGU
Val GUG
260
Asn AK
230 Pro CCC
Cys
200 Arg
-~ Lys UGC
Ala GCC
170 Val Leu GULJ CUG
CGC
Gly CGA
140 Asp GAU
Lys AAG
Val Pro GIJG Ccc
Gin CAG
Arq AGG
Gnc U~IJ Gee
Val GUA
Gly GGU
110 Lys AAG
Asp GAU
Leu
Asn AAU
Lys AAG
Val GUA
Leu Tyr CUG UAC (A)
Asn AAC
Gee
Thr ACA
80 His Glu CAC GAG
Glu GAG
Ala Pro GCIJ CCG
Asp
Glu GAG
50 Asn Thr AAC ACC
Glu GAG
Val GUA
Ala
Ile AUU
20 His Arg CAC CGA
Ala GCU
Leu Phe ClJIJUUC
Thr ACC
Ile AUC
AGCCCACUGCChAUAAACAGC~JAUUUAAGGGGnnAAnnnAAA----------
Ser AGU
Gly GGG
Asp GAC
Gly GGC
Gly GGG
Ser UCC
Glu GAG
Lys AAG
-Ser Lcu Ala CUC, GCU Gly GGC
30 Leu Ala CUG GCU
ala GCC
Thr KU
Gln CAA
240 Thr ACC
210 Ala GCA
360 Asn AAC
330 Arg CGA
Val 1l.c Lys AUC AAG
His CAU
Ala GCC
Lys AAG
Pro CCC
Ala GCU
Ile AUU
Gly GGA
Ala GCC
363 Tyr UAC
Lcu Ala ClJG GCC
Arg CGA
Gly GGG
tcr UAA
Asn AAC
Ala WC
GLn CAG
Glu GAG
Glu GAG
Leu CUG
Leu CUC
His CAC
Glu GAA
Ser UCG
Gly GGG
Ser KC
Val GUG
Ile AUU
Ser UCU
Glu GAG
Gln CAA
Ala GCU
Ala GCA
Ile Ala AU11 GCC
Asp GAC
Ala Cys GCrJ UGU
ala GCC
GAA
Glu
Glu GAA
Ser AGU
Pro CCU
Pro ccc
Asp GAC
Lys RAG
Arq CGU
Ser AGC
Pro CCG
340 Gly GGA
310 Leu CUA
280 Ser KC
250 Met AUG
220 His CAU
Glu GAG
Gly GGCJ
Cys LIGC
Arq CGC
Lys AAG
Lys AAG
Lys AAG
Ile AUC
Ala GCA
Ile Val GUC
{Le~clld o*ipage21,
Tyr []A('
Ala WII
Asn AAC
Thr AC(
Tyr UA[I
Pro CCIJ
Leu Ala CIIC GCC
Ser UCU
Gly GGU
190 Ile Leu AUU CUC
130 Leu CUG 160 Ala Ser ucc
100 Lys AAG
70 Asn Pro AAU CCC
40 Ala Lys GCC AAG
10 Glu Gln GAG CAG
CChGAGCUGAlJClJAAGGCUGCUCCAUCGACA
Ser AGC
Thr ACU
Ceu CUG
Ile AUC
~Asp GAC
Gly GGA
L,eu Thr CUG ACC
Val Glu G[JG GAG
His CAU
Gly GGG
Val GUU
Asp GAU
Thr ACU
Ala GCA
T,eu Gln CIIG CAG
Ser AGU
Tyr ~- His 1,~s Phe Ser Asn AAA lJUU IJCC AAU
Tyr Gly [JAI1GGC
Ser UCU
Gln CAG
Ala Val Tyr GClJ GIJC UAC
Ile AUU
Val GUA
Thr ACU
180 Asn Gly AAlJ GGC
300 Ser UCC
Str UCU
Thr ACU
Ser UCC
--~~~ Phc Pro Gin IJUC CCC CAA
Leu CUG
Glu GAG
Pro CCA
Ile tily Glu RUIJ GGG GAG
Thr ACC
Pro CCC
Leu CUG
Asp GAC
His Tyr UAC
150 Val T,eu Lys GIJC CUA AAG
270 Phe Leu UIJC CUG
Cys UGC
Lcu CUC
Gln CAG
Cys mxi
Arg CGC
Ala GCA
1 Ser Pro 111s Pro CCC CAC CCA
60 _.__ Gln Leu CAA CUG 90 (Ala) Asp Gly Arg GAU GGC CGU (C) ~_~~ -120 Asn Gly Glu AAU GGC GAG
Ile AUC
Phe UUC
Thr AYU
Thr ACU
Ala GCU
Val GUA
Gln CAG
Arg CGC
Thr ACC
~.. Asp GAU
Phc Ilr lJUC AK
Tyr UAC
Ltu UUG
Val GUC
His CAU
Lys AAG
Cys UGC
Trp uGG
Gly GGA
~-Ala GCA
-Phe Tyr UlJC UAC
Lys AAG
NNNNGCIJGCUGACCAGGCUCIJGCGGCUUCllIJUCAC!JGCACCAc:AGcAAAGCGCUGCCACCGGCACC
Met AUG
21
agreement
with that of rabbit
from the mRNA for
12 aa,
homology
M
aldolase A deduced
indicating (97%).
remarkably
There
high
sequence
S
H
M
28S+
is also a high sequence
homology between the noncoding regions, especially between the 3’ regions, although they are considerably
B
sequence (Tolan et al., 1984) except
23S-,
different in length (Fig. 3). This size differ-
ence seems to be caused sequence and/or seen in Fig. 3.
by insertions
deletions
in the rabbit
in the rat sequence,
18s-, 16S+
as
Comparison of the sequence of rat aldolase A with those of rat aldolase B (Tsutsumi et al., 1984a) shows that many aa substitutions occurred between these enzymes (Fig. 2). The homology between the aa sequences was 70%. The 3’-noncoding regions of the mRNAs for rat aldolases A and B are quite different in length (182 nt for aldolase A and 384 nt for aldolase B) and have no significant sequence
Fig. 4. RNA various cellulose agarose
filters
of aldolaseA
Poly(A)‘RNAs
after
mRNAs
expressed
were blotted
electrophoresis
gels (Maniatis
translated
homology. On the other hand, the 5’-noncoding regions are similar in length; yet no significant sequence homology was observed.
blot-analysis
rat tissues.
on
pRAAM83
[32P]cDNA
insert
pg), brain (B, 5 pg), heart
(H, 5 pg) and spleen (S,I5pg).M,
region
: NNNNGCUGCUGACCAGGCUCUGCGGCUUCUUUCACUGCACCAC AGGAAAGCGCUGCCACCGGCACC . . . _.. . .._. . . . . . . ..-. .._..._e... ..-....--.. ACUACUGCUGACCAG CUCUGCGGCUCCUACAGCCUCGCCGCAAGGAACU UGCUACCAGCACC Rabbit:
AUG---
Rat
3.noncoding : --UAA --UAA
Rabbit:
.._
..
.-..._..
..
..
.-
AUG---
region
CCAGAGCUGAUCUAAGGCUGCUCCAUCGACACUCCAGGCCCCUGCCU
.
(Mukai
muscle (M, 0.25
markersarerRNAs.
5 noncoding
Rat
?a
with a nick-
as described
RNAs are from skeletal
in
nitro-
formaldehyde-l
et al., 1982) and hybridized
et al., 1984). Poly(A)+
onto
..--.._--..
ACCCA
. . ._
.. ..
GCGGAGGUGUUCUAAGGCCGCCCCCUCAACACUCCACUCCAGGCUCCAGCACCGGCCCCCCUACACACACA
CUUGCUAUUGAAGAGGG GCCUU CAGGCUC UUUCCCAUCACUCUUGCUGCCCUCGUG . . . . . .-........ . . .. .-...m _..._.. _..._..._ _...__.. CUCGCUCUUGAAGAGGGAGCCUUCUUGGGGGUUCCAGGCUGUGUUUCCCACCACUCUUGCCUCCCUCGUGACUUUGG
UGUGCAGUGUUGUCUGUGAAUGCUAAAUCUGCCAUC CCUUCCAGCCCACUGCCAAUAAACAGCUAUUUAAGGGG . ... . . ..-...-. . . . . - . . . . . . . . _.._..._....._..._..._............._ UGUGUGGUAUUGUCUGUGUACGCUAUAACU CCAUCACUUUCCAGCCCACUGCCAAUAAACAGCUAUUUAAGGGGG Fig. 3. Homologous and rabbit
mRNAs
sequences
and 221 nt, respectively.
aa sequence indicate
of aldolase
ofthe pRAAM83
A mRNA
indicate
aldolase
The 3’ sequences identical
from rat skeletal
in the mRNA sequence of the primer
region is also underlined.
mRNAs
aldolase
A are shown
previously
are from the pRAAM103
used for the primer extension
was determined
are unknown
and 103 inserts are shown. Those nt in parentheses
the HhaI site, which is a 3’ terminus
The 5’-noncoding
AAA--
sequences
of the rat
are composed
of 182
nt.
muscle. The sequence
aa in rabbit B reported
A mRNAs.
of the rat and rabbit
The initial four nt of the 5’ terminus
from those of rat aldolase
insert; the nt at the same positions signal in the 3’-noncoding
of rat and rabbit
A is also shown. The different
those that are different
the sequences
two sequences
and 103, and by primer extension. of rat aldolase
regions
of 66 and 62 nt, respectively.
Dots between
Fig. 2. Nucleotide sequence pRAAM83
of the noncoding
are composed
AAAA--
(Tsutsumi
from the cDNA
and are indicated
inserts
of
by N. The deduced
above the rat sequence.
Bars on the aa
et al., 1984a). Two discrepancies
between
under codons No. 83 and 90 are from the pRAAM83 insert. GCGC experiment
in the 5’.noncoding
described
region indicates
in Fig. 6. The polyadenylation
22
(d) Aldolase A mRNAs regions
with different 5’-terminal
reported
(Mukai
for the mRNA Aldolase
A mRNAs
sues were analyzed
expressed
smaller
in various
by blot-hybridization
The aldolase A mRNA slightly
than
(Fig. 4).
from skeletal
those
from
rat tis-
muscle
other
was
tissues
as
A cDNA
3'
Tsutsumi
et al.,
to be approx.
1.55 kb
from skeletal muscle and 1.60- 1.65
kb for those from other tissues. We performed
an experiment
analogous
to that
described by Hagenbtichle et al. (1981) to locate the sequence that is responsible for the size difference. The aldolase A mRNA was hybridized with the
portion
mRNA
by digestion
RNA fragments
1
RNaseH
ization
with RNase
H. The 5 ’ and 3 ’
were then analyzed
with appropriate
by blot-hybrid-
5’- and 3’-specific
probes
prepared from the cDNA clones (Fig. 5). A size difference of approx. 50-100 nt was detected with the mRNA fragments bearing the 5’ end, but not with the 3’ fragments. For further analysis of the 5’
B a 1
1984;
220-bp HinfI fragment of pRAAM83 and cleaved into two fragments by removing the hybridized
fragment
w
5’
et al.,
1984b). The size was estimated
portion of the mRNA, cDNA was synthesized on the mRNA by primer extension using the Hhal-A/u1 cDNA fragment of pRAAM103 (Fig. 1) as a primer
b
and analyzed on a urea-PA gel (Fig. 6). Three major cDNA products, designated as I, II and III, whose sizes were estimated to be 110, 160 and 205 nt, respectively, were observed in the mRNAs from different tissues. The major cDNA product of the mRNA from skeletal muscle was cDNA I, whereas those of mRNAs from other tissues were cDNA II and III. The size difference between cDNA I and II or III was approx. 50-100 nt, which corresponded
12
2
-
1630
-
520
-
M
-
H
B
S
L - 1631
-
Fig. 5. Location (A) Schematic molecules
of size
220
in aldolase
of the procedure
into 5’ and 3’ fragments
fragment
-
difference
representation
J510 394 - 344 - 290
with RNase
used is the 220.bp ffinfl fragment
insert (see Fig. 1). (B) Blot-hybridization ments of aldolasc and
ascites
express heart,
a longer aldolase mRNAs
gels and blotted hybridized
onto GeenScreen
species
(bp) are Hbzfl-digested
(lane 1)
is known
on glyoxal,‘2”,, filters (NEN).
pBR322.
Fig. 6. Analysis
of cDNA
results).
minal region ofaldolase
agarose
DNA
Filters
ofpRAAM
is shown
products
synthesized
on the 5’-tcr-
A mRNA by primer extension.
in Fig.
I. Poly(A)’
RNAa
are from
A primer skeletal
were
muscle (M, 2 keg), heart muscle (H. 4 pg), brain (B, 4 pg), spleen
103
(S, 15 llg), and adult liver (L, IO pg). 0.08 pmol of the primer
probe or (b) 460-bp P.ul fragment
insert as a 3’-specific
primeL
to
like those of brain,
with either of(a) 1X0-bp PstI fragment cDNA
muscle
et al., 1984 and unpublished
were electrophorcsed
cDNA
of the 5’ and 3’ frag-
(lane 2), which
A mRNA
insert as a 5’-specific
of pRAAM83
H. The cDNA
of pRAAM83
from rat skeletal
AH60C
and spleen (Mukai
Cleaved
cDNA
A mRNAs
hepatoma
A mRNAs.
to cleave mRNA
probe. Size markers
DNA
was hybridized
products
with each
were subjected
gels (Maxam
and Gilbert.
poly(A)
to elcctrophoresis
’ RNA. The cDNA on 50’1,J urea:X”,, PA
1980). Size markers
are as in Fig. 5.
23
to the differences between seen in Fig. 4 and 5.
the sizes of the mRNAs
between
cDNA
I (110 nt) and cDNAs
and 205 nt) is in agreement between
aldolase
A mRNAs
II, III (160
with the differences in skeletal muscle and
other tissues observed in Figs. 4 and 5. If this is the case, the difference between two aldolase A mRNA DISCUSSION
species is located
in the region upstream
from the
HhaI
site (3’ terminus of the primer DNA) in the 5’-noncoding sequence. When aldolase A mRNAs
We have isolated several cDNA clones corresponding to a nearly entire region of aldolase A mRNA from rat skeletal muscle. We observed that
in skeletal muscle and brain were blot-hybridized with the cDNA fragment upstream of the HhaI site
there were several microheterogeneities in the nt sequences among the cDNA clones analyzed (Fig.
in the 5’-noncoding sequence of pRAAM 103 insert, a hybridization band was observed in skeletal muscle
2). It is most likely that these heterogeneities
poly(A) + RNA but not in brain poly(A) + RNA (not
resulted
from a heterogeneous mRNA population arising from allelic variation, since the mRNA used for cDNA cloning was prepared from many rat individuals. The observed aa change (Fig. 2) does not affect the net charge of the protein and probably not the enzymatic properties. Such allelic variation or polymorphism may be ubiquitous in eukaryotic genomes, since electrophoretic variants which arose from allelic variations have been reported for many enzymes or proteins of vertebrates, including man, and insects such as Drosophila (Johnson, 1977; Koehn and Eanes, 1979; Kreitman, 1983). Aldolase A mRNA in skeletal muscle is slightly shorter than those in other tissues (Fig. 4). This difference is mainly in the 5’ portion of the mRNA, not merely in the length of the poly(A) tail because, as seen in Fig. 5, only 5’ fragments of the mRNAs show a size difference which agrees well with the difference between the intact mRNAs observed in Fig. 4. It is therefore concluded that at least two species of aldolase A mRNA, whose 5’ portions are of different lengths, are expressed in a tissue-specific manner; i.e., the shorter one is in skeletal muscle and the longer one is in other tissues. Furthermore, three cDNA products with different lengths were produced by primer extension (Fig. 6). Although we cannot exclude the possibility that these cDNA products were produced by multiple premature terminations of cDNA synthesis on an aldolase A mRNA, it is more likely that cDNA I was synthesized on the shorter mRNA abundant in skeletal muscle and cDNA II and III were on the longer one abundant in other tissues by the following reasons. First, cDNA I is a major product only with mRNA from skeletal muscle and a very minor one with mRNAs from other tissues. Second, the size difference
shown). This observation suggests that two aldolase A mRNA species differ not only in length but in the nt sequence of the 5’-noncoding region. Comparing the rat and rabbit aldolase A mRNAs, highly homologous sequences were found in both the 5’- and 3’-noncoding regions, as shown in Fig. 3. In contrast, no distinct homologous sequence was found in either noncoding region between rat aldolase A and B mRNAs. The divergence of aldolase A and B genes should have occurred before the appearance of vertebrates, i.e., prior to the divergence of the rat and rabbit aldolase A genes, because these isozymes have been found in all the vertebrates so far examined (Lebherz and Rutter, 1969). Therefore, the presence or absence of homologous sequences in the noncoding regions may be explained by the difference in time after divergence ofthe genes. Alternatively, it may also be possible that the common sequences in the noncoding regions of the aldolase A mRNAs carries a regulatory function specific for aldolase A gene expression.
ACKNOWLEDGEMENTS
an
We thank Dr. M. Ikehara for generously providing antibody against rat aldolase A and Dr. Y.
Nabeshima for valuable suggestions about the preparation of RNA from skeletal muscle. This investigation was supported in part by a Grant-in-aid for Scientific Research from the Ministry of Education, Science and Culture of Japan.
24
Markert.
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