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J. Biol. Chem., Vol. 277, Issue 40, 37464-37468, October 4, 2002
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From the
Received for publication, June 18, 2002, and in revised form, July 15, 2002
A combination of sequence profile searching and
structural protein analysis has revealed a novel type of small molecule
binding domain that is involved in the allosteric regulation of
prokaryotic amino acid metabolism. This domain, designated RAM, has
been found to be fused to the DNA-binding domain of Lrp-like
transcription regulators and to the catalytic domain of some metabolic
enzymes, and has been found as a stand-alone module. Structural
analysis of the RAM domain of Lrp reveals a Allosteric regulation is a general mechanism that enables a tight
control of both enzyme activity and gene expression. A textbook example
of this mechanism is the feedback inhibition of enzymes that catalyze
key steps in amino acid biosynthesis. Important insight in the
molecular basis of modulated enzyme activity has been
provided by the crystal structure of 3-phosphoglycerate dehydrogenase (SerA) (1, 2), an enzyme that catalyzes the rate-limiting first step in
serine biosynthesis. The SerA structure has revealed separated
catalytic and regulatory domains that are connected by a flexible
hinge. The structural motif of the regulatory domain consists of a
four-stranded anti-parallel A thorough sequence profile analysis has shown that the SerA regulatory
domain is an ancient small molecule binding domain (SMBD)1 that is conserved in
a wide variety of enzymes as well as in some transcriptional regulators
that are involved in the control of amino acid and purine metabolism
(4). As predicted in the latter study, the presence of this ancient
"ACT domain" (for review see Ref. 5) was indeed demonstrated in the
recent crystal structures of rat phenylalanine hydroxylase (6),
an enzyme that catalyzes the conversion of phenylalanine to
tyrosine. Interestingly, the structure of the Escherichia
coli threonine deaminase (7), the enzyme catalyzing the first step
of the isoleucine biosynthesis pathway, revealed two domains that
resembled the ACT domain of SerA at the structural level rather than at
the sequence level (4). This observation demonstrates that the sequence
divergence of SMBDs like ACT can expand beyond the detection limits of
the sequence-based algorithm of PSI-BLAST (8). For this reason, the
threonine deaminase-ACT domains have been referred to as "ACT-like" domains (5).
In the present study we describe a novel ligand-binding module that we
named the RAM domain because of its general involvement in the
allosteric Regulation of Amino acid
Metabolism. This domain is mainly found in association with
a class of prokaryotic transcriptional regulators but also as a module
in enzymes and in some instances as stand-alone SMBD.
PSI-BLAST Analysis and Multiple Sequence Alignments, Domain
Analysis of Proteins--
In order to verify and characterize the
relationship between distant RAM domains at the sequence level, we
performed several PSI-BLAST searches (8) at the National Center of
Biotechnology Information. When a PSI-BLAST search was seeded with the
C-terminal domain of the Pyrococcus furiosus LrpA (residues
62-141), using a BLOSUM80 matrix and an expect value threshold of
0.001, the first stand-alone versions of RAM (lacking the HTH domain)
were retrieved within the first iteration (10580664;
E = 6 × 10 Structural Alignment and Superimposition Three-dimensional
Structures of SerA ACT Domain and LrpA RAM Domain--
In order to
detect the structural similarity of ACT and RAM, a superimposition of
the C-terminal domain of the P. furiosus LrpA (residues
64-135) and the ACT domain present in the SerA of E. coli
(residues 335-410, PDB entry 1PSD) was constructed using the Swiss PDB
viewer (12) using the "Iterative fit" option. The superimposition
was constructed with 49 The Structure of the C-terminal Domain of LrpA Resembles Structure
of the ACT Domain--
The Lrp family of transcriptional regulators
plays a crucial role in the control of amino acid metabolism in
prokaryotes. Although the leucine-responsive regulatory protein (Lrp)
from E. coli is a global transcriptional regulator (13),
most Lrp homologs act as specific regulators (e.g. Refs.
14-16). The interaction of specific amino acid effectors with Lrp-like
regulators may lead to modulation of (i) DNA affinity, (ii) DNA
bending, (iii) Lrp oligomeric state
(dimer/tetramer/octamer/hexadecamer), and (iv) Lrp tertiary structure
(13, 15, 16, 17). All these changes most likely reflect an allosteric
regulation of Lrp activity by a (minor) structural rearrangement.
Recently, the structure of an archaeal Lrp homolog, the P. furiosus LrpA octamer (or tetramer of dimers), has been
resolved (18). The structure of the LrpA monomer revealed an N-terminal DNA-binding helix-turn-helix (HTH) domain, an extended hinge, and a
C-terminal globular domain with a
The overall structural resemblance between the RAM domain of the
P. furiosus LrpA and the ACT domain of the E. coli SerA is confirmed by superimposition of both structures (Fig.
1a). The obtained root mean
square deviation value between the LrpA-RAM and the SerA-ACT (1.8 Å)
compares with a value obtained with a superimposition between SerA-ACT
and the ACT domain of the rat phenylalanine hydroxylase (1.7 Å).
Ligand Response Mutations in RAM and ACT Suggest a Different
Location of the Ligand-binding Sites in RAM and ACT--
Despite the
structural similarities between the RAM domain and the ACT domain,
however, the effector-binding sites in these domains seem to be
different. In the ACT domain of SerA, the loop that links the first
The dimer structure of the SerA-ACT differs significantly from the
LrpA-RAM dimer. Whereas the contact between the two ACT domains seems
to be mediated via the The RAM Domain Has a Wide Phyletic Distribution and Is Present in
Transcriptional Regulators, Metabolic Enzymes, and as a Stand-alone
Version--
In order to verify and characterize the relationship
between distant RAM domains at the sequence level, we performed several iterative data base searches (PSI-BLAST) (8) at the National Center of
Biotechnology Information, revealing the ubiquitous phyletic
distribution of this domain among Archaea and Bacteria (>250 proteins
after 5 iterations). The proteins that were retrieved during this
search were dominated by the Lrp-like regulators, typically consisting
of an N-terminal DNA-binding helix-turn-helix domain fused to a
C-terminal RAM domain (HTH-RAM). An interesting variant of HTH-RAM is a
duplicated version, found in some bacteria (Streptomyces
sp.); this supports the view that the native form of
Lrp-like transcriptional regulators is at least a dimer configuration. In addition, examples were found of a RAM domain that was fused to the
C terminus of 2-isopropylmalate synthase (IPMS) in the Crenarchaea
S. solfataricus (SSO0977), S. tokodaii
(ST1301), and Pyrobaculum aerophilum (PAE1986). Also several
stand-alone RAM domains were detected with the PSI-BLAST search (Fig.
3). This variable domain architecture of
RAM again resembles that of the ACT domain. ACT is found as an
allosteric regulatory domain associated with metabolic enzymes (like
SerA, phenylalanine hydroxylase and threonine deaminase) and
transcriptional regulators (like TyrR and PhhR) as well as a
stand-alone version (IlvH) (Fig. 3). It is noted that the RAM domains
are mainly associated with transcriptional regulators, whereas the ACT
domain is most often found as a regulatory module of metabolic
enzymes.
The A more clear-cut example is the anticipated role for the RAM domain
that is present at the C terminus of the crenarchaeal IPMS. Generally,
IPMS catalyzes the first step in leucine biosynthesis that is subjected
to leucine-mediated feedback inhibition. Leucine has the following two
known effects on this enzyme in Salmonella typhimurium: (i)
it controls the catalytic activity of the enzyme by feedback inhibition
(22), and (ii) it causes a dissociation of the tetrameric enzyme into
its monomeric subunits (23). Genetic mapping of leucine-insensitive
mutants (24, 25) revealed that the mutation resulting in the affected
end product inhibition is located at the C terminus of the S. typhimurium IPMS. So the domain that is probably responsible for
the allosteric control of IPMS is located in the C-terminal part of the
enzyme. Sequence analysis of the C-terminal part of the S. typhimurium IPMS did not reveal the presence of a RAM or
ACT domain, possibly suggesting the presence of yet another alternative
regulatory domain. Although the exact mechanism of inhibition remains
to be elucidated, the presence of a C-terminal RAM domain in the
crenarchaeal RAM-IPMS strongly suggests that these enzymes are
subjected to RAM-mediated feedback regulation.
The date presented here indicate that structure-based alignments of the
regulatory domains as well as extensive (reverse) PSI-BLAST analyses
fail to close the apparent gap in sequence divergence between RAM and
ACT. This might suggest that ACT and RAM both have independently
evolved into allosteric regulatory domains. However, the most
parsimonious scenario is that the two domains have emerged from a
common ancestor and only evolved different interaction specificity with
respect to their ligands. Possibly, the diversification in binding
sites is the underlying reason of the dramatic sequence divergence
between RAM and ACT, with the overall structure being well conserved.
This appears to be yet another example of domain evolution in which
sequence similarity has been lost while retaining their structural
similarity (26).
We thank Dr. Eugene V. Koonin (National Center
of Biotechnology Information, Bethesda) for stimulating discussions.
*
The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
The atomic coordinates and the structure factors (code 1I1G) have been deposited in the Protein Data Bank, Research Collaboratory for Structural Bioinformatics, Rutgers University, New Brunswick, NJ (http://www.rcsb.org/).
§
To whom correspondence should be addressed. Tel.: 31-317-483110;
Fax: 31-317-483829; E-mail: Thijs.Ettema@algemeen.micr.wau.nl.
Published, JBC Papers in Press, July 23, 2002, DOI 10.1074/jbc.M206063200
The abbreviations used are:
SMBD, small molecule
binding domain;
PDB, Protein Data Bank;
IPMS, 2-isopropylmalate
synthase;
HTH, helix-turn-helix.
A Novel Ligand-binding Domain Involved in Regulation of Amino
Acid Metabolism in Prokaryotes*
§,,
, and
Laboratory of Microbiology, Wageningen
University, Hesselink van Suchtelenweg 4, NL-6307 CT Wageningen,
The Netherlands, the Department of Molecular Biology and
Biotechnology, Krebs Institute for Biomolecular Research, University of
Sheffield, Western Bank, Sheffield S10 2TN, United Kingdom, and the
¶ Department of Biological Chemistry, University of Michigan
Medical School, Ann Arbor, Michigan 48109-1055
ABSTRACT
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-fold
that is strikingly similar to that of the recently described ACT
domain, a ubiquitous allosteric regulatory domain of many metabolic
enzymes. However, structural alignment and re-evaluation of previous
mutagenesis data suggest that the effector-binding sites of both
modules are significantly different. By assuming that the RAM and ACT
domains originated from a common ancestor, these observations suggest that their ligand-binding sites have evolved independently. Both domains appear to play analogous roles in controlling key steps in
amino acid metabolism at the level of gene expression as well as enzyme activity.
INTRODUCTION
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-sheet with two -helices packed on
one side. When the serine effector molecule binds to this
-sandwich, the hinge region allows allosteric regulation: a
slight interdomain rearrangement that down-regulates the catalytic activity of the enzyme (2, 3).
EXPERIMENTAL PROCEDURES
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12); the RAM domains
within the Sulfolobus solfataricus and Sulfolobus tokodaii 2-isopropylmalate synthase (13814162, respectively, 15623321) were recovered in iteration 3 (E = 7 × 106). A reverse PSI-BLAST
using the S. solfataricus 2-isopropylmalate synthase
sequence (residues 342-461) recovered HTH-RAM proteins (e.g. 13813287 at iteration 1, E = 3 × 105) and stand-alone versions of the RAM domain
(e.g. 13813398 at iteration 2, E = 5 × 105), thereby connecting the most distant RAM domain
containing proteins with each other on a statistical basis. A multiple
alignment of RAM domains was constructed by collecting the "highest
scoring pairs of sequence segments" using PSI-BLAST, which were
re-aligned using ClustalW (9), followed by minor manual adjustment
based on the secondary structure. Domain analysis of RAM- and
ACT-containing proteins was performed using SMART (10) an PFAM (11).
All protein sequences were extracted from ENTREZ.
-carbon atoms that displayed a root mean
square value of less than 2.5 Å, comprising about 65% of the domains.
From the superimposed structures, a structural alignment was deduced
using the Structural alignment tool of the Swiss PDB viewer (12).
RESULTS
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-fold. Previous mutagenesis analyses were in perfect agreement with the N-terminal domain being involved in the interaction with DNA and predicted the
C-terminal -sandwich to have a regulatory function (18, 19). What
was not noted during the initial analysis of the LrpA structure is the
interesting fact that the C-terminal regulatory domain of LrpA
appears to resemble the ACT domains (4, 5) with respect to
structure and function; both consist of a typical -sandwich and
are anticipated to be regulatory domains involved in allosteric
modulation of the activity of enzymes and DNA-binding proteins that are
involved in amino acid metabolism. Despite the similarity in structure
with the ACT domain, we propose that, for reasons discussed below, the
C-terminal regulatory domain of LrpA is part of a novel, distinct class
of regulatory domains.
View larger version (41K):
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Fig. 1.
a, superimposition of the RAM
domain of the P. furiosus LrpA (purple) with the
ACT domain of the E. coli SerA (yellow) showing
the strong similarity between the two domains at the structural level
(root mean square deviation value 1.8 Å). The superimposition was
constructed with 49 -carbon atoms, which composes about 65% of the
domains. In addition, the position of the negative effector of SerA ACT
domain, serine, was indicated within the superimposed domains.
Superimposition and figure were created using the Swiss PDB viewer
(19). b, structural alignment of the RAM domain of the
P. furiosus LrpA (residues 64-135) and the ACT domain of
the E. coli SerA (residues 335-410). In addition, the 80%
consensus sequences for RAM and ACT domains are included in the
alignment indicating the sequence divergence between the two SMBDs. For
abbreviations of the different amino acid classes see Fig. 2. Matched
residues that display a root mean square value of less than 2.5 Å are
boxed. The structural alignment was constructed using the
Swiss PDB viewer (19) using the "Structural alignment" option.
c, structural comparison of the RAM dimer of P. furiosus LrpA (left) and ACT dimer of E. coli SerA (right). The monomers are shown in
cyan and blue, and the ligand response mutations
of the RAM domain and the ACT domain corresponding to those that are
depicted in Fig. 2, a and b, respectively, were
mapped into the backbones of the respective structures in
red with magenta side chains.
-strand (1) and the first -helix (1) of the
-fold, makes up the binding pocket of the serine effector. The important role of this loop is in agreement with the fact
that it is very well conserved in ACT-containing enzymes and regulators
(Fig. 2a). An invariant
glycine residue, which is also conserved in the ACT-like domains
of the E. coli threonine deaminase, and an adjacent
hydrophobic residue have been proposed to be involved in maintenance of
the strand-helix interface; two additional conserved polar residues are
involved in binding the ligand with hydrogen bonds (1, 4). The
importance of the conserved region was also confirmed by mutation
analysis of other ACT-containing enzymes from E. coli,
i.e. the valine-binding regulatory subunit of the
acetolactate synthase (IlvH) (20) and the lysine-sensitive aspartokinase (LysC) (21) (Fig. 2a). Mutations that resulted in a strongly reduced or abolished response after being exposed to
their respective effector (ligand response mutations) all cluster within the conserved loop region, suggesting that binding of the effector resembles the interaction of SerA with serine. Mapping the ACT
ligand response mutations into the structure of the ACT dimer of SerA
(Fig. 1c) confirms this idea. The ligand response mutations
cluster at the dimer interface in general and at the ligand
(serine)-binding site in particular (Fig. 1c).
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Fig. 2.
a, an alignment of the most diverse
members of the ACT domain. The secondary structure assignment that is
indicated above the alignment was derived from the crystal
structure of the E. coli 3-phosphoglycerate dehydrogenase
(SerA; PDB code 1PSD). The amino acid residues that are involved in the
binding of the effector serine in SerA, are indicated above
the alignment (x). In addition, the ligand response
mutations that were determined for the E. coli small subunit
of the acetolactate synthase (IlvH) and aspartokinase (LysC) are
indicated with * and $, respectively. The 80%
consensus shown below the alignments was obtained as
described above, and the position numbers on the left side
indicate the limits of the domains. Also a structural alignment of the
two regulatory ACT-like domains of the E. coli threonine
deaminase (THD1) is included, with a mapped ligand response
mutation (+), indicating the divergence on the sequence level between
these domains and the genuine ACT domains. Secondary structure from the
first repeat of THD1 is indicated above the alignment. The
80% consensus shown below the alignments was obtained using
the following amino acid classes (4): small (s, ACGSTDNVP;
shaded yellow), polar (p, YWHKREQDNST;
shaded green), big (b, FILMVWYKREQ; gray
shading), and hydrophobic (h, ILVCAGMFYWHTP;
shaded black). Of the hydrophobic residues, the aliphatic
subset (h, ILVA) is in black with
red shading. The position numbers on the left
side indicate the limits of the domains. b, a multiple
alignment of RAM domains. By using the structure of P. furiosus LrpA (7), the secondary structure of the RAM domain has
been deduced, as is indicated above the alignment (E,
-strand; H, -helix). The sequences are grouped by
domain architecture as follows: 1, Lrp-like transcriptional
regulators and homologs (HTH-RAM); 2, stand-alone versions
of the RAM domain; 3, duplication of Lrp-like
transcriptional regulator; and 4, RAM domain present in
crenarchaeal 2-isopropylmalate synthase. The ligand response mutations
as determined for the E. coli Lrp by Platko and Calvo
(19) are indicated above the alignment (#). All
protein sequences were obtained from ENTREZ, and GenBankTM
identifiers are indicated for each protein. Species abbreviations are
as follow: Aea, Aquifex aeoliticus;
Afu, Archaeoglobus fulgidus;
Atu, Agrobacterium tumefaciens;
Bsu, Bacillus subtilis; Ccr,
Caulobacter crescentus; Eco, E. coli;
Mlo, Mesorhizobium loti; Mtu,
Mycobacterium tuberculosis; Pab, Pyrococcus
abyssi; Pfu, P. furiosus;
Pho, Pyrococcus horikoshii; Pmi,
Proteus mirabilis; Pmu, Pasteurella
multocida; Ppu, Pseudomonas putida;
Sco, Streptomyces coelicolor;
Sno, Streptomyces noursei; Sso,
S. solfataricus; Sto, S. tokodaii; and
Tvu, Thermoplasma vulcanium.
2 and 3 interface resulting in an
eight-stranded anti-parallel -sheet (1), in LrpA the RAM dimer is
mainly formed by interactions between the antiparallel -sheets that
are facing each other, forming an antiparallel -barrel-like structure (Fig. 1c) (18). Because of this structural
difference, and given the fact that the ligand-binding site for ACT
domains is located at the dimer interface, this might imply that the
ligand-binding site is different in RAM domains. Indeed, the region
that is involved in interaction with the ligand (Fig. 2a) is
well conserved in ACT domains, whereas the corresponding loop that
links strand 1 and helix 1 in RAM domains displays only poor
sequence conservation (Fig. 2b). In RAM, the best conserved
region, again including an invariant glycine residue, appears to be the
region surrounding the loop connecting strands 2 and 3. Moreover,
extensive mutagenesis studies that have been performed with the
E. coli Lrp (19) confirm the importance of this region with
respect to ligand response. The Lrp leucine response mutations that
were obtained in this study apparently lost the capacity to bind their
ligand (19). When the equivalents of these E. coli Lrp
ligand response mutations are mapped into the structure of the LrpA-RAM
dimer of P. furiosus, it becomes clear that five of seven
mapped mutations belonging to this class (Leu-95, Met-101, Ala-134,
Ile-135, and Ile-136) are clustered in a region across the dimer
interface (Fig. 1c). The remaining two ligand response
mutations (Gly-111 and Gly-123) are located in close proximity to the
other mutations, albeit in adjacent dimers of the octamer rather than
within the same dimer (18) (not shown in Fig. 1c). These
observations suggest that the ligand-binding site of RAM is located at
a different position than that of ACT. Based on the relatively high
sequence conservation and to some extent on the mutation data, it is
tempting to speculate that the ligand-binding site of RAM is located
between the 2 and 3. Lrp ligand co-crystallization experiments
are required to confirm this hypothesis.
View larger version (33K):
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Fig. 3.
Domain architectures of ACT and RAM
containing proteins, subdivided into three classes according to their
function. For each class of proteins, the phyletic distribution is
depicted below the domain structure. Domain analysis was
performed using SMART (20). Apart from the regulatory domains (ACT or
RAM), the other domains that are part of the proteins are described as
follows. a, transcription regulation-associated regulatory
domains. 1, Lrp-like transcriptional regulators, generally
consisting of an N-terminal DNA-binding helix-turn-helix domain fused
to a C-terminal RAM domain; 2, duplicated form of Lrp-like
transcriptional regulator, consisting of a tandem repeat of the
transcriptional regulator; 3, transcriptional regulator of
aromatic amino acid biosynthesis, containing an N-terminal ACT domain,
followed by a PAS domain which is possibly involved in signal sensing.
The C-terminal part of these regulators contain a sigma54
interacting domain (PF00989) and a DNA-binding helix-turn-helix
(hth_8; PF02954). b, enzyme-associated regulatory
domains. 1, Crenarchaeal 2-isopropylmalate synthases,
containing an HMGL-like domain, which is found in a diverse set of
enzymes including several aldolases and a pyruvate carboxylase;
2, aspartokinases, containing an N-terminal kinase domain
(PF00696) that is involved in phosphorylation of a variety of amino
acid substrates; 3, diverse group of proteins involved in
biosynthesis of aromatic amino acids consisting of prephenate
hydratases, chorismate mutases, and phenylalanine hydroxylases. From
the latter enzyme the domain architecture is displayed, containing a
biopterin_H domain (PF00351), which is present in
biopterin-dependent aromatic amino acid hydroxylases;
4, group of proteins consisting of 3-phosphoglycerate,
homoserine, and malate dehydrogenases, containing an N-terminal
2-Hacid_DH catalytic domain (PF00389) and a NAD-binding
domain (2-Hacid_DH_C, PF02826); 5,
formyltetrahydrofolate deformylases, typically containing a C-terminal
formyl_transf. domain (PF00551), a domain that is present in
multiple enzymes that are involved in de novo purine
biosynthesis; 6, diverse set of proteins containing
uridylyltransferases that are involved in glutamine synthase regulation
(GlnD), guanosine polyphosphate 3'-pyrophosphorylases (SpoT), and GTP
pyrophosphokinases (RelA). The latter two enzymes are involved in
stringent response. The domain architecture that is depicted here
represents GlnD, containing a nucleotidyltransferase domain
(NTP_transf, PF01909) and an HDc domain that is involved in
metal-dependent phosphohydrolase activity. c,
stand-alone regulatory domains. 1, small regulatory domain
of the acetolactate synthase, generally consisting of a N-terminal ACT
domain fused to a small domain that is probably involved in the
interaction with the large subunit (IlvI); 2, isolated RAM
domains. The function of these proteins is still to be elucidated;
however, it is possible that they play a role analogous to the isolated
ACT domains, i.e. regulatory subunit of enzymes or
transcriptional regulators.
DISCUSSION
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EXPERIMENTAL PROCEDURES
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DISCUSSION
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-motif appears to be a common regulatory
structure in amino acid metabolic enzymes and transcriptional
regulators; both the RAM and the ACT domains share this fold and are
associated with proteins that are involved with amino acid metabolism
either as part of enzymes, as part of transcriptional regulators, or as
stand-alone SMBD. Apart from the structural and functional similarity
between the two domains, another connection is the fact that the
expression of some bacterial ACT-containing enzymes (e.g.
SerA and IlvHI) is under control of RAM-containing transcriptional regulators of the Lrp family (9). These observed analogies between RAM
and ACT may be useful for speculating about the function of
uncharacterized RAM and ACT domains. For example, the function of the
stand-alone versions of the RAM domains that are present in several
bacterial and archaeal genomes is yet unclear. However, the function of
stand-alone ACT domains might suggest the possible function of their
stand-alone RAM counterparts. For example, the acetolactate synthase in
E. coli is a key enzyme in branched chain amino acid
biosynthesis that is subjected to valine feedback inhibition (19). The
heterotetrameric holoenzyme is made up of the large catalytic subunit
(IlvI) and a small regulatory subunit that consists of a single ACT
domain (IlvH) and accounts for the valine-mediated feedback repression.
It is possible that a stand-alone RAM domain performs a function that
is analogous to that of the IlvH subunit, allosteric regulation of
enzymes (or possibly transcriptional regulators) involved in amino acid
metabolism via protein-protein interactions. Interestingly,
profile-based analysis of prokaryal genomes (e.g. S. solfataricus) failed to identify a gene encoding the small
regulatory subunit of the acetolactate synthase (IlvH), whereas
homologs of the gene encoding the large catalytic subunit of the
acetolactate synthase could be identified on the genome (e.g. ilvB-1). Possibly, the large subunit of the
acetolactate synthase present in these organisms are subjected to
allosteric regulation by the stand-alone RAM domains that are encoded
on the genome.
ACKNOWLEDGEMENT
FOOTNOTES
ABBREVIATIONS
REFERENCES
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REFERENCES
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