(Received for publication, July 25, 1996, and in revised form, November 25, 1996)
From the Departments of Genetics and Pediatrics,
§§ Program in Developmental Biology, and
** Division of Biochemistry Research, Research Institute, The Hospital
for Sick Children, 555 University Avenue, Toronto, Ontario M5G 1X8,
Canada and the Departments of ¶ Molecular and Medical Genetics and
Biochemistry, Faculty of Medicine,
University of Toronto, Medical Sciences Building,
Toronto, Ontario M5S 1A8, Canada
To determine the molecular and biochemical basis of intragenic complementation observed at the human argininosuccinate lyase (ASL) locus, we identified the ASL alleles in ASL-deficient cell strains with two unique complementation phenotypes: (i) frequent complementers, strains that participated in the majority of complementation events, and (ii) high activity complementers, strains in which complementation was associated with a relatively high level of restoration of ASL activity. Four mutations (Q286R, D87G, A398D, and a deletion of exon 13) were identified in the four strains examined. One of the two frequent complementers was homozygous, and the other heterozygous, for the Q286R allele. Similarly, one of the two high activity complementers was homozygous, and the other heterozygous, for the D87G allele. When the Q286R and D87G mutations were introduced by site-directed mutagenesis into wild-type ASL cDNA, each conferred loss of ASL activity in COS cell transfection assays. To test directly the hypothesis that intragenic complementation occurs at the ASL locus, one of the major complementation events observed previously, between strains carrying the Q286R and D87G alleles, was reconstructed in COS cell transfection assays. A partial restoration of ASL activity, comparable with the increase seen in the fibroblast complementation analysis, was observed on joint cotransfection of these two alleles. The results provide molecular confirmation of the major features of the ASL mutant complementation map, identify the Q286R and D87D alleles as the frequent and high activity complementing alleles, respectively, and provide direct proof of intragenic complementation at the ASL locus.
Argininosuccinate lyase (ASL,1 EC 4.3.2.1) deficiency is an autosomal recessive disorder of the urea cycle with substantial clinical and genetic heterogeneity (1-4). The clinical heterogeneity of the disease is manifested by variations in the age of onset and the severity of symptoms, with patients classified into three distinct clinical groups: neonatal onset, subacute onset, and late onset. The biochemical basis of this clinical variation is unclear, since there is only a partial correlation between the clinical phenotype and the residual enzyme activity detected in cultured fibroblasts (2) or other tissues (1). The ASL enzyme, which catalyzes the reversible breakdown of argininosuccinate into arginine and fumarate, is a homotetramer of 50-kDa subunits (5-7).
Genetic heterogeneity in ASL deficiency has been identified by complementation analysis using cultured fibroblasts from 28 unrelated patients (2). All ASL-deficient strains map to a single complementation group (i.e. affect a single locus), but the structure of the complementation map and the nature of the complementation events suggest that extensive interallelic complementation is present at this locus, and 12 distinct complementation subgroups were defined (2). The affected gene at the locus was confirmed to be ASL by the identification of the molecular defect in one cell strain belonging to the single complementation group (8). This strain (944) has a homozygous single substitution that converts an arginine to a cysteine residue in codon 95 (R95C) and produces a complete loss of ASL activity (8). Other mutations in the ASL gene have been described by Barbosa et al. (4). Additional evidence for genetic heterogeneity has been obtained from immunoblot studies of the abundance of ASL protein in patient fibroblasts (3). Although most strains examined have some detectable ASL cross-reacting material of normal size (50 kDa, ASL monomer), its abundance varies widely in cells from different patients.
To begin an analysis of the molecular basis of the intragenic complementation at the ASL locus, we have identified the ASL mutations in the two classes of ASL-deficient strains with the most unique complementation phenotypes: the "frequent" and "high activity" complementers (2). We chose to study the frequent complementer strains 926 and 1254 (2) because one or the other of them participated in almost all (30 of 32) of the positive complementation events observed. The designation "high activity" complementer was conferred on two other strains (1182 and 1253) because, when they were fused with either of the frequently complementing strains 926 or 1254, the restoration in ASL activity was significantly greater (~10-fold) than that seen (~3-fold) with any other complementation events (2). Strains 1182 and 1253 are the only members of the high activity complementer class, and they belong to the same complementation subgroup (2). The fact that the complementation behavior of a pair of strains is so similar suggests that each member of the pair shares at least one allele in common or that their ASL alleles have very similar effects on the protein.
In this paper we report the identification of the alleles in ASL-deficient strains from the frequent and high activity complementers and demonstrate that strains with similar complementation behavior share the same alleles. The identification of the alleles in complementing ASL-deficient strains has also allowed us to obtain direct proof of intragenic complementation by reconstruction of one major complementation event in COS cells. Taken together, these results confirm major features of the intragenic complementation map constructed for the ASL locus (2). In addition, they establish that the Q286R and D87G alleles account for the frequent and high activity complementing phenotypes, respectively, of ASL-deficient cells that carry them. Each of these substitutions impairs enzyme function sufficiently to cause disease but not to the extent that some amelioration of the function of one mutant subunit by another is prevented in a heteroallelic ASL tetramer. Although the molecular basis of the increase in ASL activity that occurs in the complementing heteroallelic ASL tetramer is unknown, recent determination of the x-ray crystal structure of ASL2 suggest that the recovery of partial ASL activity may be due to the formation of one or more "native-like" active sites (9) rather than the conformational correction (9) of one mutant monomer by the other.
Fibroblasts were cultured in -minimal
essential medium without antibiotics and supplemented with 10-15%
fetal bovine serum as described previously (2, 3). The clinical
phenotype and complementation behavior of all strains discussed in this
paper have been reported previously (2).
The oligonucleotide primers used for PCR
amplification of single-stranded ASL cDNA, based on the ASL
cDNA sequence of Todd et al. (10), are numbered using
the initial nucleotide of the translated sequence as the first
nucleotide. The complete coding sequence and short flanking sequences
were amplified in three overlapping fragments. The 5 fragment was
amplified using primers 12 (nucleotides
27 to
3) and 22 (nucleotides 445-468) (Table I), the middle fragment using primers 32 (nucleotides 400-426) and 42 (nucleotides 943-966), and the 3
fragment using primers 52 (nucleotides 910-936) and 62 (nucleotides
1396-1422). Each primer contained at its 5
end the nine-base pair
sequence, CCTGGATCC, containing a BamHI restriction
site.
|
For single-stranded gel electrophoresis (SSGE) and direct sequencing,
the cDNA was amplified a second time from one of the three
overlapping fragments described above, as 1 of 10 overlapping fragments
(~230 bp each) that spanned the complete cDNA. These fragments
corresponded to the 10 regions of the cDNA sequence indicated in
Table I. Genomic PCR was performed using a primer (primer J)
corresponding to the 3 end of intron 10 (11), which had the sequence
5
-GCCAGCACCTCTGTCCCCAG-3
, and primer 42 (Table I). Reverse
transcription, amplification, and cloning of the amplified material
were performed as described by Walker et al. (8).
The plasmid pESP-SVTEXP (pESP) is
an expression vector containing the SV40 early promoter and the SV40
polyadenylation signal (12). The pESP-SVTEXP/ASL plasmid (pESP-WT),
constructed using standard techniques (13), contained a full-length
normal ASL cDNA (14) with 20 bp of untranslated 5 sequence and 46 bp of untranslated 3
sequence. The Q286R mutation was introduced into the ASL cDNA by the site-directed mutagenesis method of Kunkel (15), and the mutagenized cDNA was cloned into the pESP-SVTEXP vector (pESP-Q286R). Since strain 1253 was found to be homozygous for
the D87G allele, the D87G expression vector was created by PCR using
primers 12 and 22 (Table I) to amplify the region of the 1253 cDNA
(nucleotides
27 to 468) that contained the mutation. After digestion
of this fragment with MluI and Bsu36I,
nucleotides 74-360 were then subcloned into the pESP-WT plasmid,
replacing the normal sequence in this region (pESP-D87G). The entire
ASL coding region of the control and mutant expression vectors and of
the DNA flanking the ligation sites was sequenced to ensure that no
mutations, other than those introduced specifically, were present. An
expression vector (pXGH5) (16) containing the mouse metallothionein-1
promoter controlling the full-length human growth hormone gene was used
as a control for transfection efficiency of COS cells.
The PCR products were amplified as indicated above but without the use of 35S-labeled nucleotides. The PCR products were then partially purified and concentrated using Millipore Ultrafree-MC 30,000 NMWL filter units according to the manufacturer's instructions. Approximately 100 ng of the partially purified PCR products were then asymmetrically amplified (17) under the same PCR conditions but with 100 ng of one primer only. The asymmetric PCR products were sequenced using standard conditions using the U.S. Biochemical Corp. Sequenase sequencing kit.
Transient Expression Analyses of ASL cDNAsTransfection of the expression vectors was performed by the method of Chen and Okayama (18). Approximately 106 COS-1 cells were plated in a 100-mm Petri dish. One to two days later, the pESP-SVTEXP vector (20 µg) alone or this vector with either a normal or mutant (Q286R, D87G, or both D87G and Q286R) full-length ASL insert (20 µg) and 5 µg of pXGH5 were transfected by calcium phosphate co-precipitation and harvested after 72 h. Following transfection, the cells were used to prepare RNA and crude cell lysates for protein and enzyme assays.
Cell lysis, protein electrophoresis, and ASL immunoblotting were done as described previously (3). The anti-ASL antibody has been described (6). Assays of human growth hormone were performed by the Allegro assay system, as suggested by the manufacturer (Nichols Institute Diagnostics). Protein was measured by the method of Lowry et al. (19) using bovine serum albumin as a standard.
Enzyme Assays of Cell ExtractsASL enzyme activity was
assayed as described previously (20). All ASL assays were performed in
triplicate (three different dishes) for each expression vector. ASL
activity was calculated by first subtracting the average ASL activity
from mock-transfected plates of COS-1 cells from the ASL activity of
the COS-1 cells transfected with the normal and mutant alleles to
remove background. ASL activity was then normalized for transfection
efficiency by dividing the ASL activity of a cell extract by the
relative human growth hormone activity of each plate. The specific
activity of cell extracts was determined by dividing the ASL activity
by the densitometry values of the ASL band from immunoblots of total protein from each dish. The densitometry values used for each transfection were the average ASL protein band intensity from the
immunoblots of the three transfections performed in one experiment with
each construct (see Fig. 3 and Table II).
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Isolated restriction fragments were radiolabeled to a specific activity greater than 108 cpm/µg using random oligonucleotide primers (21). Radiolabeling of oligonucleotides was done by the phosphate exchange method as described by Sambrook et al. (13). Single-stranded DNA for sequencing was prepared from Bluescript clones by the method of Vieira and Messing (22) and sequenced by the dideoxy method, using T7 or internal primers and Sequenase (23). SSGE was performed as described previously (24). Southern and RNA blots were done using standard methods (13) and were hybridized with a full-length ASL cDNA (14).
To identify the mutations in the four cell strains being studied (the two frequent complementers (926 and 1254) and the two high activity complementers (1182 and 1253)), we first established that gross alterations or rearrangements of the ASL gene were not present. EcoRI- or BglI-digested genomic DNA of all four strains was examined by Southern blot analysis. No changes in the size of the restriction fragments were seen in any strain (data not shown). The relative abundance and size of the ASL mRNA was also determined on blots of total RNA. All four strains had ASL mRNA of normal size and of an abundance comparable with controls (data not shown), indicating that at least one ASL allele in each strain produced near normal amounts of ASL mRNA.
Mutation Analysis of the Frequent Complementer Strains (926 and 1254)We initially sought to identify the ASL mutation in strain
1254, since the patient from whom this strain was derived was the product of a consanguineous mating and therefore likely to be homozygous for a single mutant allele. The ASL mRNA was
reverse-transcribed, amplified in three overlapping fragments of ~500
bp, and cloned into the Bluescript vector. The sequence of seven clones
of each fragment demonstrated only one consistent nucleotide change, a T C transition at nucleotide 857 of the noncoding strand, in exon
11 (Fig. 1a). This mutation, an A
G
transition in the sense strand of the second nucleotide of codon 286, changes the codon from glutamine to arginine (Q286R).
To confirm that the nucleotide change observed in the cloned cDNA
was present in both alleles of the genomic DNA of strain 1254, a
genomic fragment containing exon 11, exon 12, and the intervening
sequence was analyzed by amplification and restriction enzyme
digestion. The A G transition creates new restriction sites for
NciI (recognition site: CC(C/G)GG), ScrFI
(recognition site: CCNGG), and HpaII (recognition site:
CCGG) within the amplified fragment of the mutant. Genomic DNA from 5 control and 11 ASL-deficient patients was also amplified and digested
with NciI. The results obtained for strains 926 and 1254 (the frequent complementers) and two controls are shown in Fig.
2a. The restriction fragments from the three
other control DNAs and the nine other DNAs from ASL-deficient patients
were identical to the controls shown in Fig. 2a and are not
presented. The data demonstrated that strain 1254 is homozygous for the
Q286R mutation, as expected from the parental consanguinity. The
amplified DNA from strain 926 generated both the ~175- and ~125-bp
fragments (Fig. 2a), suggesting that this strain is
heterozygous for the NciI site introduced by the A
G
mutation and that it therefore also carries the Q286R allele.
The results obtained from the three diagnostic restriction enzyme
digestions for strains 926 and 1254 were confirmed using DNA amplified
in a second PCR reaction. The results of the digestion of the DNA with
the three enzymes were identical to those obtained initially (data not
shown). To confirm that codon 286 of strain 926 contained the identical
substitution to that found in strain 1254, and to identify the mutation
in the other allele of this strain, the entire cDNA was amplified
in three overlapping ~500-bp fragments spanning the ASL cDNA, as
described above. Gel electrophoresis of the 3 fragment demonstrated
the presence of a small (~450-bp) as well as a normal sized
(~530-bp) band (data not shown); the other two fragments were of
normal size. Direct sequencing of the smaller fragment, cut from the
gel, showed that this allele lacked exon 13, a human ASL mutation
reported previously by Barbosa et al. (4). All three ASL
cDNA fragments of normal size were subcloned and sequenced. As
expected, the only substitution present was that which creates the
Q286R allele, the A
G transition at the second position of codon
286 (data not shown). The Q286R allele was not identified in any of the
other 28 strains that had been examined by complementation analysis at
the ASL locus nor in 20 control
alleles.3
To identify the ASL mutations in strain 1253, 10 overlapping fragments of ~225 bp each, using the primers shown in
Table I, were amplified from the three major ASL
cDNA fragments. The ~225-bp fragments were examined for mutations
by SSGE. A homozygous single-stranded conformational variant was
observed in the third cDNA fragment (Table I), which direct
sequencing (Fig. 1b) revealed to be an A G transition at
nucleotide 260, in exon 3. This substitution converts an aspartic acid
to a glycine residue at codon 87 (D87G) and creates a novel
SfaNI site. Restriction analysis was used to confirm that
strain 1253 was indeed homozygous for the mutation (Fig.
2b).
Since strains 1253 and 1182 are the only two members of the high
activity complementation subgroup (2), we examined the cDNA of
strain 1182 for the D87G mutation using restriction analysis with
SfaNI (Fig. 2b), which indicated that this cell
strain is heterozygous for the D87G mutation. This result was confirmed by direct sequencing (data not shown). Of the 28 ASL-deficient cell
lines studied (2), 1182 and 1253 were the only two strains found to
have the D87G mutation, and this allele was also absent from 20 control
alleles.3 The mutation in the second allele of strain 1182 was identified by SSGE analysis and direct sequencing to be a C A
transversion at nucleotide 1193 in exon 15 (data not shown). This
substitution destroys an existing HaeIII restriction site
and results in an alanine to aspartic acid substitution at codon 398 (A398D). No other mutations were detected by SSGE and direct sequencing
of the ASL cDNA of either strain 1182 or 1253.
Since strain 1254 (frequent complementing phenotype) and strain 1253 (high activity complementing phenotype) are homozygous for the Q286R and D87G alleles, respectively, interaction between the Q286R and D87G polypeptides would appear to be responsible for the partial restoration of ASL activity (i.e. complementation) observed in cell fusions of fibroblasts carrying these alleles (2). To examine this hypothesis directly, we used transient expression assays in COS-1 cells to reconstruct the complementation event between the products of the Q286R and D87G alleles. We first demonstrated that the Q286R and D87G mutations produced significant reductions of ASL activity. We then reconstructed the complementation event between Q286R and D87G by co-transfecting these alleles into COS-1 cells to determine whether the resultant ASL activity was greater than could be achieved by the transfection of either allele alone.
After cloning the wild-type and mutant ASL cDNAs in the pESP-SVTEXP expression vector, the entire cDNA insert and its flanking sequences were sequenced in each construct to confirm that no other mutations had been introduced during either the mutagenesis or cloning. COS-1 cells were transfected with the vector containing the normal (pESP-WT) or mutant (pESP-Q286R or pESP-D87G) cDNAs or both of the mutant cDNAs. A Northern blot of total RNA from transfected cells probed with labeled ASL cDNA demonstrated that ASL mRNA was generated from both the control and mutant (D87G, Q286R, and D87G/Q286R) ASL expression vectors (data not shown). The transfected ASL mRNA was slightly larger than the native message because the predominant polyadenylation signal is located in the vector sequence (12). Immunoblot analysis demonstrated ASL protein of the expected size in cells transfected with both the normal and mutant cDNAs (Fig. 3), although significant differences in the abundance of the ASL protein were observed when equivalent amounts of total cell protein (1 µg) were loaded in each lane (Fig. 3 and Table II). No discernible ASL protein was seen in the mock-transfected cells (Fig. 3). The relative amount of ASL protein produced in COS-1 cells by each construct was determined by densitometric analysis (Table II).
Assay of ASL specific activity in the transfected cells demonstrated that the Q286R mutation virtually ablates ASL activity, to less than 0.05% of control levels (Table II). Transfection of the empty SV-TEXP vector resulted in no detectable increase in ASL activity (not shown). The specific ASL activity of cells transfected with the control cDNA, calculated as shown in Table II, was 2000 ± 330 pmol/mg of cell protein/min (n = 3) (Table II, column 5), compared with 0.93 ± 0.15 pmol/mg/min (n = 3) for cells transfected with the Q286R construct. The D87G mutation, in contrast, reduced the ASL activity to about 5% of controls: 92 ± 42 pmol/mg/min. (n = 3) (Table II, column 5). Cells transfected jointly with the D87G and Q286R alleles demonstrated a more than 10-fold increase in activity (610 ± 89 pmol/mg/min (n = 3), or 30% of control) compared with the mean of the two activities (~2.5%) obtained from the transfection of either allele alone (Table II, column 5). These results provide direct evidence that the D87G and Q286R alleles complement.
Considerable indirect evidence indicates that extensive allelic heterogeneity characterizes human ASL deficiency. This evidence includes both the occurrence of intragenic complementation (2) as well as variation in the abundance of the ~50-kDa ASL monomer in patient fibroblasts (3). The impression of substantial genetic heterogeneity is further supported by the identification of four alleles (Q286R, D87G, A398D, and the exon 13 deletion) in the four strains studied here, by the description of six different mutations in the ASL gene in four patients reported by Barbosa et al. (4), and by the demonstration of another allele, R95C, in an additional patient (8). That both strains 1253 and 1254 have homozygous ASL mutations reflects the derivation of these cells from patients whose parents were consanguineous. The D87G mutation was observed only in the two high activity complementer strains (1182 and 1253) and not in the other 26 ASL-deficient strains on which complementation analysis was performed (2). Although Q286R was also observed in one patient by Barbosa et al. (4), there is no evidence that the three ASL-deficient patients with the Q286R allele (two in our study and the patient of Barbosa et al.) are related, and its absence in 52 other ASL-deficient alleles that we examined indicates that it is not particularly common. The loss of activity in the Q286R protein demonstrated in the transient expression studies is clearly not due to a decrease in the subunit stability alone, since the monomer is present at an abundance of ~23% of the wild-type subunit, yet the protein has no measurable ASL activity (Fig. 3 and Table II). Consequently, the major effect of the Q286R mutation is to perturb the catalytic function of the ASL protein. The ablative effect of the Q286R substitution on ASL activity is consistent with all three patients with at least one Q286R allele (the donors of fibroblast strains 1254 and 926 from this study, and patient AR of Barbosa et al. (7)) having the severe neonatal onset form of the ASL deficiency.
The effect of the D87G mutation on catalytic activity, shown by the transient expression studies, is less severe than that of Q286R. The D87G ASL monomer was of reduced abundance (~22% of control) in the transient expression studies but still formed an ASL enzyme with ~5% of the activity of controls (Fig. 3 and Table II). The decreased but measurable ASL activity of the D87G protein is reflected in the moderately less severe clinical phenotype (the subacute form of the disease) of the patient homozygous for this allele, and in the mild (late onset) phenotype of the patient who is a D87G heterozygote. The very mild clinical phenotype of this D87G heterozygote, whose other allele is A398D, suggests that the latter allele may also have significant residual ASL activity.
Our studies demonstrate clearly that Q286R is the frequently complementing allele of human ASL deficiency. It is the only ASL allele present in one frequent complementer (strain 1254) and the only complementing allele present in the other frequent complementer studied (strain 926). Strain 926 also carries the exon 13 deletion allele. A deletion of exon 13 was reported in one case described by Barbosa et al. (4) and shown to result from a 13-bp deletion within exon 13 that leads to exclusion of this exon from the transcript; the exon 13 deletion seen in strain 926 is due to the identical 13-bp deletion.3 Although the removal of exon 13 from the transcript would maintain the reading frame to produce an ASL polypeptide shortened by 28 residues, this protein lacking exon 13 does not complement, since we have found this mutation3 in strains that do not complement at all, such as 1040 (2). Thus, the complementation behavior of strain 926, which carries both the 13-bp deletion of exon 13 and the Q286R alleles, can be attributed entirely to the latter. Neither the complementation properties of the Q286R allele nor the effect of this mutation on ASL activity were examined by Barbosa et al. (4).
The evidence that the D87G allele is the high activity complementation allele is similarly strong. It is the only ASL allele present in one high activity complementer (strain 1253), and it is also present in the only other strain (1182) that manifests the high activity complementation phenotype. We cannot exclude the possibility that the other allele carried by strain 1182, A398D, may also confer the property of high activity complementation in association with Q286R subunits. However, it is not necessary to invoke any complementation properties for the A398D allele to account for the high activity complementation behavior of strain 1182, which can be related solely to the D87G polypeptide.
The relatively high degree of restoration of ASL activity observed when cells with the D87G allele are fused with cells carrying the Q286R allele must therefore reflect interaction between Q286R and D87G ASL subunits. Formal proof of this interaction has been obtained from the transient co-expression of the Q286R and D87G alleles in COS cells. The co-expression of these two alleles leads to an approximate 10-fold increase in the observed ASL activity over the cells transfected with only one of these alleles alone (Table II). The ASL activity observed in the co-transfected cells was approximately 30% of that obtained with the wild-type ASL allele in the transient expression system. Since the complementation-related increase in ASL activity that resulted from the fusion of cells containing the Q286R and D87G alleles was substantially higher than any other increase observed (2), we conclude that the formation of the heteroallelic Q286R:D87G tetramer is the most successful intragenic complementation event that has been observed to date at the ASL locus.
The complementation patterns for strains 1254 and 926 are comparable but not identical. Strain 1254 complements 14 strains, while 926 complements 10 strains. Eight strains are complemented by both (2). The similar complementation behavior of these two strains and the fact they do not complement each other led us to predict that they would share an allele or at least have alleles with similar, if not identical, effects on the protein (2). The identification of the Q286R allele in these two strains with comparable complementation behavior therefore partially confirms the complementation map at the molecular level.
Since strain 1254 carries only the Q286R allele and strain 926 carries one copy of Q286R together with a likely null allele (the exon 13 deletion), one might expect that both strains would have identical complementation patterns. The fact that they do not may be due to the presence of twice the number of Q286R subunits in strain 1254, which is homozygous for this allele, compared with strain 926, which is heterozygous. Thus, the failure to observe complementation between strain 926 and strains that complemented strain 1254 (2) may be a dosage effect, reflecting the comparatively lower amounts of Q286R polypeptides in strain 926. The reason that complementation was not observed between strain 1254 and two strains that complemented strain 926 (2) is not clear. One possible explanation is that the discrepancy may only be apparent because in the original complementation analysis the failure to detect complementation between two strains on an initial fusion was not re-evaluated in any subsequent experiment. Positive complementation tests, in contrast, were validated repeatedly (2). Alternatively, the ASL subunit produced from the other allele of strain 926 (the exon 13 deletion) may be capable of complementing some ASL alleles that the Q286R subunit cannot. However, given the frequent complementation phenotype of the Q286R allele and the severe alteration in subunit structure that would result from the absence of the 28 amino acids (residues 327-355 of the ASL subunit) encoded by exon 13, this explanation seems unlikely.
One other allele, R95C, is known to be capable of complementing Q286R. Strain 944, which is homozygous for this allele (8), complements strain 1254 (homozygous for Q286R) (2), producing a small (~3-fold) but significant increase in ASL activity (2). The difference in the amount of ASL activity recovered from the Q286R:D87G (~10-fold) and Q286R:R95C (~3-fold) heteroallelic tetramers reflects, at least to some extent, differences in the stability of the individual mutant alleles involved, since transient expression studies of the R95C allele demonstrated that little or no R95C ASL monomer could be detected, and thus no ASL activity was measurable (8). The absence of complementation between strains with the R95C allele (strain 944) and those with the D87G allele is perhaps not surprising, since the proximity of the two affected residues may produce similar rather than complementary effects on the ASL protein.
ASL and -crystallins belong to a superfamily of metabolic enzymes
that all function as tetramers and catalyze homologous reactions. Duck
and chicken
-II-crystallins, proteins found in the eye lenses of
birds and reptiles, have been found to be directly related to ASL, not
only in the primary sequences of the gene and protein (25, 26), but
also functionally, since crystallins exhibit ASL activity (27-29).
Apart from enzymes with ASL activity, members of this superfamily
include fumarase (30), aspartase (30), adenylosuccinase (31), and
3-carboxy-cis,cis-muconate lactonizing enzyme (32).
When the enzyme superfamily is considered as a whole, three regions of
closely conserved amino acid sequence are highlighted, corresponding to
residues 110-121, 157-166 and 280-294 of the human ASL sequence.
Comparison of the ASL sequence between residues 280 and 290 (inclusive)
with other members of the superfamily (Fig.
4a) shows that 8 of these 11 residues are
identical. The glutamine at position 286 is the least conserved residue
in this region, but the transient expression studies we performed
demonstrate that this mutation was not a benign sequence variant. Based
on the similarity of the reactions catalyzed by these proteins, the conservation of these sequences across the superfamily, and their location in the putative active site of the enzyme2 (33,
34), these 11 residues have been suggested to play an important role in
the catalytic mechanism (30, 33, 34). This suggestion is supported by
the dramatic effect on catalysis of the Q286R mutation, which is
located in this region. In addition, our preliminary data on the
structure of ASL2 suggest that the loop on which
Gln286 is located forms one part of active site bowl of the
ASL tetramer. The aspartic acid residue at position 87 is close to the
first conserved region (residues 110-121) of the whole ASL family of proteins (Fig. 4b), and this residue also appears to be
located within the active site cleft.2
Intragenic complementation is a phenomenon that occurs between different mutants of multimeric proteins. Positive complementation, observed after fusion of two different mutant cell strains or by mixing cell extracts, produces an increase in functional activity that is greater than that seen in either mutant alone (35, 36). Studies in Neurospora crassa and Escherichia coli have shown that complementation is due to the formation, from different mutant polypeptides, of hybrid multimers that are able to produce increased, although not normal, enzyme activities (36). Crick and Orgel (9) suggested that the recovery of activity in a hybrid tetramer could be due either to (i) regeneration of native active sites, an alternative which they dismissed because it seemed unable to account for nonlinear complementation maps, or (ii) conformational correction of one mutant subunit by another. Of these two possible explanations for the complementation we observed at the ASL locus, we favor the former because it is consistent with our preliminary structural analyses of human ASL.2 Our preliminary data suggest that the ASL active site is formed at the interface between three monomers, with four active sites per tetramer. Consequently, due to the symmetry of the molecule, it appears likely that in a Q286R:D87G heteroallelic tetramer at least one and possibly two "wild-type" active sites will be formed, a mechanism that is possible because in any one active site, residues 87 and 286 would be contributed by different monomers. Thus, if one active site of the hybrid tetramers contains both mutant residues, another will contain normal residues at both positions and will hence reconstruct a native active site. If this model of regeneration of a wild-type active site proves to be correct, it would also explain why D87G and R95C do not complement, since one or the other of these mutations would be present in every active site. Based on this hypothesis, one would also predict that complementation could occur between A398D and Q286R subunits. Tetramers constituted from A398D and Q286R subunits could have at least one normal active site in which residues 398 and 286 are contributed by different monomers.
The characterization of the molecular basis of intragenic complementation in human ASL deficiency outlined in this paper, together with the structural determination of ASL,2 should facilitate the use of ASL as a model for the study of genetic diseases affecting multimeric enzymes. The results of these two studies show that the interaction of the two alleles in a patient who is a genetic compound (as the majority of patients probably are (2)) may sometimes ameliorate the biochemical phenotype of the patient. The net residual ASL activity will not be the average of the two alleles, but it will be greater due to the complementation of the two alleles. When such complementation occurs, a clinical phenotype may be produced that is less severe than that resulting from either point mutation expressed homozygously. Individuals with complementing alleles that lead to relatively high ASL activity may be biochemically normal and not have argininosuccinic aciduria. More generally, such interactions must be considered in any attempt to correlate patient phenotypes with the genotype of patients with mutations affecting multimeric proteins.
We thank D. Mahuran for helpful discussions.