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Plant Physiol, June 2001, Vol. 126, pp. 696-706
Inventory of the Superfamily of P-Type Ion Pumps in
Arabidopsis1
Kristian B.
Axelsen and
Michael G.
Palmgren*
SwissProt Group, Swiss Institute of Bioinformatics, 1 rue Michel
Servet, CH-1211 Geneva 4, Switzerland (K.B.A.); and Plant Physiology
and Anatomy Laboratory, Department of Plant Biology, The Royal
Veterinary and Agricultural University, Thorvaldsensvej 40, DK-1871
Frederiksberg C, Copenhagen, Denmark (M.G.P.)
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ABSTRACT |
A total of 45 genes encoding for P-type ATPases have been
identified in the complete genome sequence of Arabidopsis. Thus, this
plant harbors a primary transport capability not seen in any other
eukaryotic organism sequenced so far. The sequences group in all five
subfamilies of P-type ATPases. The most prominent subfamilies are
P1B ATPases (heavy metal pumps; seven members), P2A and P2B ATPases (Ca2+ pumps; 14 in total), P3A ATPases (plasma membrane H+
pumps; 12 members including a truncated pump, which might represent a
pseudogene or an ATPase-like protein with an alternative function), and
P4 ATPases (12 members). P4 ATPases have been
implicated in aminophosholipid flipping but it is not known whether
this is a direct or an indirect effect of pump activity. Despite this apparent plethora of pumps, Arabidopsis appears to be lacking Na+ pumps and secretory pathway (PMR1-like)
Ca2+-ATPases. A cluster of Arabidopsis heavy metal pumps
resembles bacterial
Zn2+/Co2+/Cd2+/Pb2+
transporters. Two members of the cluster have extended C termini containing putative heavy metal binding motifs. The complete inventory of P-type ATPases in Arabidopsis is an important starting point for
reverse genetic and physiological approaches aiming at elucidating the
biological significance of these pumps.
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INTRODUCTION |
The P-type superfamily of ion
pumps includes primary transporters energized by hydrolysis of ATP with
a wide range of specificities for small cations and perhaps also
phospholipids (Møller et al., 1996 ; Palmgren and Harper, 1999). P-type
ATPases are characterized by forming a phosphorylated
intermediate (hence the name P-type), by being inhibited by vanadate,
and by having a number of sequence motifs in common (Serrano, 1989;
Axelsen and Palmgren, 1998). Plant P-type ATPases are characterized
structurally by having a single subunit, eight to 12 transmembrane (TM)
segments, N and C termini exposed to the cytoplasm, and a large central
cytoplasmic domain including the phosphorylation and ATP binding sites
(Fig. 1).
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Figure 1.
Overview of the Arabidopsis P-type ATPase
superfamily. Families are designated by numerals on the left followed
by gene names. The putative transported ions are indicated on the
right. Boxes indicate transmembrane segments; black circles, regulatory
domains containing autoinhibitory sequences; white circles, HMA
domains; black boxes: CC dipeptide domains; white boxes,
poly-His domains. HMA, CC dipeptide, and poly-His domains are
putatively involved in heavy metal binding and sensing. Abbreviations
are: 14-3-3, 14-3-3 protein binding region; CaM, calmodulin binding
region; and PL, phospholipids.
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The P-type ATPase family can be divided into five major evolutionarily
related subfamilies, which group according to the ions they transport
(Axelsen and Palmgren, 1998; Fig. 1). The P-type ATPases are involved
in a wide range of fundamental cellular processes such as making and
maintaining the electrochemical gradient used as the driving force for
the secondary transporters (H+-ATPases in plants
and fungi and
Na+/K+-ATPases in animals),
cellular signaling (Ca2+-ATPases), the transport
of essential micronutrients (Zn2+- and
Cu2+-ATPases), and extrusion of the same ions if
they accumulate in amounts that are too high. P-type ATPases may also
be involved in the generation of membrane lipid asymmetry (Tang et al.,
1996; Gomes et al., 2000).
Although P-type ATPases can be completely absent from certain bacterial
and archaean genomes (e.g. Borrelia burgdorferi and Pyrococcus horikoshii), they constitute a large and
indispensable family in eukaryotes as demonstrated by the completely
sequenced genomes of the organisms Saccharomyces cerevisiae,
Caenorhabditis elegans, and Drosophila
melanogaster. With the completion of the Arabidopsis genome, it is
possible for the first time to study the primary transport capabilities
of a plant and to compare plant transport with that of animals,
insects, and fungi.
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THE P-TYPE ATPase SUPERFAMILY IN ARABIDOPSIS |
The first remarkable fact is the number of P-type ATPases found in
Arabidopsis. A total of 45 P-type ATPases was identified in the genome
of Arabidopsis (Table I). This is
the highest number of P-type ATPases found so far in a single organism.
Arabidopsis harbors more than double as many P-type ATPases than
C. elegans (21), D. melanogaster (13; the number
is increased by gene splicing), and the yeast S. cerevisiae
(16). Even in the human genome, which is not completed yet, fewer genes
are found. Table II gives an overview of
how many P-type ATPases can be found in the different sequenced genomes
and of the distribution among the different subfamilies. Complete
sequences can be found at The P-type ATPase database Web site
(http://www.Patbase. kvl.dk).
A phylogenetic analysis of the conserved regions common to all P-type
ATPases (Axelsen and Palmgren, 1998) reveal that Arabidopsis harbors
ATPases belonging to all the five major subfamilies (Fig. 2). Several of the subfamilies such as
the P2B ATPases (the calmodulin-regulated Ca2+-ATPases) and the P3A
ATPases (plasma membrane H+-ATPases) form closely
related clusters, whereas other subfamilies are more distantly related,
most notably the P1B ATPases (heavy metal-transporting ATPases).
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Figure 2.
Phylogenetic tree of Arabidopsis P-type ATPases.
Conserved segments present in all P-type ATPases were extracted from
the sequences and were aligned using T-COFFEE (Notredame et al., 2000).
The alignment was used to perform a phylogenetic analysis using the
Protdist and Fitch program from the Phylip package (Felsenstein, 1989).
The resulting phylogenetic tree reveals five major branches, which are
named according to Axelsen and Palmgren (1998).
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P1B ATPases |
Arabidopsis is equipped with seven P1B
ATPases. Plant P1B ATPases have recently been
reviewed (Williams et al., 2000) and are expected to be involved in
the transport of heavy metals. In other organisms, pumps belonging to
this subfamily typically exhibit two substrate specificities:
either Cu2+/Ag2+ or
Zn2+/Co2+/Cd2+/Pb2+
(Solioz and Odermatt, 1995; Beard et al., 1997; Rensing et al., 1997,
1998; Thelwell et al., 1998). Multiple alignments between all
P1B ATPases identified so far in bacteria,
archaea, and eukaryotes indicate that Arabidopsis HMA1, HMA2, HMA3, and
HMA4 are likely to be
Zn2+/Co2+/Cd2+/Pb2+
ATPases, whereas RAN1, PAA1, and HMA5 are candidate
Cu2+/Ag2+ ATPases.
HMA2, HMA3, and HMA4 form a subcluster in the phylogenetic analysis
of Arabidopsis ATPases (Fig. 2), supporting the notion that they might
have a similar function.
The cDNAs of four of the P1B ATPase genes
(RAN1, PAA1, HMA1, and
HMA4) have been cloned. Only RAN1, which is 50% similar to the human Menkes and Wilson Cu2+-ATPases, has
been characterized in some detail. RAN1 has been shown to be important
for the delivery of copper ions to receptors for the plant hormone
ethylene (Hirayama et al., 1999; Woeste and Kieber, 2000) and perhaps
also to additional cuproenzymes (Woeste and Kieber, 2000). Closely
related proteins found in yeast and humans have equivalent roles, as
exemplified by the yeast Cu2+-ATPase Ccc2p, which
delivers copper ions to the iron oxidase Ftr3p involved in iron uptake
(Yuan et al., 1995), and the Menkes disease symptoms, which can be
explained by the general deficiency of copper for copper-requiring
enzymes (Danks et al., 1972).
Eukaryotes apart from plants appear to have a limited number of
P1B ATPases (one or two in each genome) and so
far those that have been identified belong to the
Cu2+/Ag2+ cluster.
Zn2+/Co2+/Cd2+/Pb2+
ATPases are common in bacteria and have not been observed in animals
and fungi (Table II). Therefore, it is noteworthy that four Arabidopsis
P1B ATPase genes encode pumps belonging to the Zn2+/Co2+/Cd2+/Pb2+-transporting
cluster. Biochemical or genetic evidence is needed to confirm the
actual transport specificity of these pumps.
In Arabidopsis, a large number of carrier proteins are involved in the
transport of Zn2+, Co2+,
and Cd2+ (Mäser et al., 2001). These heavy
metal transporters belong to two families: the Nramp family, which
contains at least seven members, five of which have been characterized
(Curie et al., 2000; Thomine et al., 2000); and the ZIP family of
approximately 13 members, four of which have been characterized (Eide
et al., 1996; Grotz et al., 1998; Korshunova et al., 1999; Guerinot,
2000). The Nramp family of proteins codes both high- and low-affinity transporters, which mainly transport Fe2+ into
the plants, but have a broad substrate specificity. It has been
demonstrated that they also transport Mn2+ and
Cd2+ (Curie et al., 2000; Thomine et al., 2000).
The ZIP transporters mainly transport Zn2+ and
Fe2+, but they also have a broad substrate range.
Why would Arabidopsis need additional primary transporters for
the transport of Zn2+, Co2+,
and Cd2+? Important roles for primary heavy
metal transporters could be the accumulation of these or other heavy
metals in subcellular compartments and/or ensuring that
the levels inside the cells do not reach toxic levels. Furthermore, the
members of the P1B ATPases could be involved in
delivering heavy metal ions to specific proteins, like is the case for
RAN1 (Hirayama et al., 1999; Woeste and Kieber, 2000). The elucidation
of the tissue distribution and subcellular locations of plant
P1B ATPases would help determine which (if not
all) of these possibilities are correct.
P1B ATPases typically have short
C-terminal domains and very large N-terminal domains containing heavy
metal-associated (HMA) domains of 31 amino acids with the signature
GMTCxxC (Bull and Cox, 1994). The HMA domains bind heavy metals and
might serve a role as heavy metal sensors. Analysis of the
P1B ATPase sequences in Arabidopsis shows a
number of interesting features. HMA domains are found in the N-terminal
regions of the candidate
Cu2+/Ag2+ ATPases RAN1 (one
domain), PAA1 (two domains), and HMA5 (two domains). However, the
Arabidopsis subgroup of putative
Zn2+/Co2+/Cd2+/Pb2+
ATPases (HMA1-4) contain no HMA domains in their sequences. Instead, several CC dipeptides and His-rich domains can be found in HMA2 and
HMA4. The His-rich domain is most evident in HMA4. It has been proposed
that CC dipeptides together with His-rich domains could be part of
non-HMA domains that are also involved in heavy metal binding (Solioz
and Vulpe, 1996; Williams et al., 2000). Furthermore, HMA2 and HMA4 are
the only P1B ATPases identified so far, which are
predicted to have a long C-terminal domain. It is interesting that the
CC dipeptides and the His-rich domains are found in the prolonged C
termini of HMA2 and HMA4 and not in the N-terminal domain where HMA
domains are always found (Fig. 1). The N-terminal end of HMA1 also
harbors a poly-His domain (Fig. 1).
Because a cDNA representing HMA2 has not been cloned,
the predicted primary sequence of the encoded protein with an extended C-terminal domain might be wrong. However, the prolonged C-terminal end
of HMA2 is encoded by a long exon including the two last transmembrane segments and part of the universally conserved ATP binding domain, and
the far C terminus shows similarity to the far C terminus of HMA4.
Therefore, the predicted gene model is likely to be correct.
The locus HMA5 is also predicted to have a prolonged
C-terminal domain, but contrary to HMA2 this domain is found
on an exon of its own and it is similar to a repeated domain found in
more than 30 copies dispersed in the genome. Furthermore, it does not contain any putative heavy metal binding domains, whereas two HMA
domains can be found in the N terminus of the protein. Therefore, we
believe the C-terminal domain is not part of locus HMA5 and have instead identified the C terminus of the protein by removal of the
two last exons and prolongation of the third last exon to the first
stop codon and found four amino acids downstream of the proposed splice
site. This yields a C terminal similar to that normally seen in
P1B ATPases. No expressed sequence tags (ESTs)
corresponding to this protein have yet been found.
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P2A ATPases |
The P2A ATPases encompass
Ca2+ ATPases similar to the animal
Ca2+-ATPases of the sarco- and endoplasmatic reticulum
(SERCA pumps) and the fungal and animal secretory pathway ATPases
(ATP2C1 in animals; PMR1 in yeast). These ATPases are also
involved in Mn2+ transport (Lapinskas et al.,
1995; Liang et al., 1997; Dürr et al., 1998). The
Ca2+ ATPases of Arabidopsis have recently been
reviewed (Evans and Williams, 1998; Geisler et al., 2000a; Sze
et al., 2000). Four P2A ATPases can be found in
the Arabidopsis genome. All four of the genes have been cloned and
ECA1-3 have been characterized (Liang et al., 1997; Pittman
et al., 1999). ECA1 and ECA4 are the two most closely related of the
P2A ATPases (97% identical) and the
corresponding genes are found within 50 kb of each other on chromosome
1, indicating a recent duplication event. ECA1, ECA2, and ECA4 form a
closely related cluster with ECA3 being more distant (Fig. 2). There is
only evidence for the subcellular location of ECA1, which has been
localized to endoplasmic reticulum membranes.
The yeast S. cerevisiae is equipped with a
well-characterized Ca2+-ATPase, PMR1, which is
situated in the secretory pathway. Here it is involved in the correct
processing of proteins exported from the cells. Very similar ATPases
have been identified in mammals (e.g. human ATP2C1 and KIAA0703). These
pumps form a distinct cluster of ATPases in the
P2A subfamily (Axelsen and Palmgren, 1998). In
Arabidopsis, however, none of the four P2A
ATPases identified resemble the secretory pathway
Ca2+-ATPases. Thus, all four pumps are much more
similar to animal SERCA Ca2+-ATPases
(approximately 50% identity) than to the secretory pathway pumps
ATP2C1 or PMR1 (approximately 32% identity).
The absence of PMR1-like pumps in Arabidopsis does not exclude the
possibility that this plant can have a
Ca2+-ATPase situated in the secretory pathway: A
number of the 14 Arabidopsis P2A and
P2B ATPases have been demonstrated in different endomembranes. Thus, it remains a possibility that one or more of these are positioned in the secretory pathway.
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P2B ATPases |
The P2B ATPases also transport
Ca2+. They are most similar to the mammalian
plasma membrane Ca2+-ATPases (PMCA pumps) and the PCA1
ATPase from yeast. The P2B ATPases have a total
of 10 members in Arabidopsis and form three clusters in the Arabidopsis
P-type ATPase tree (Fig. 2). The overall sequence identity is rather
high, ranging from 45% to 92% between the different members; but even
so, the genomic organization of the different genes differs
fundamentally. Where ACA12 and ACA13 are coded in
only one exon each, the ACA8 and ACA10 genes
consist of 34 exons.
Four of the 10 proteins (ACA1, ACA2, ACA4, and ACA8) have been cloned
and characterized in some detail (Huang et al., 1993; Harper et al.,
1998; Bonza et al., 2000; Geisler et al., 2000b). Each protein seems to
be present in a specific membrane such as the plasma membrane (ACA8;
Bonza et al., 2000), the membrane of small vacuoles (ACA4; Geisler et
al., 2000b), and perhaps the chloroplast envelope (ACA1; Huang et al.,
1993). An N-terminal calmodulin-binding domain was first identified in
the cauliflower P2B ATPase BCA1 (Malmström
et al., 1997). On the basis of sequence analyses, calmodulin-binding
domains could be identified in the first 50 amino acids of all
Arabidopsis P2B ATPases (not shown). There is
experimental evidence for the presence of calmodulin-binding sequences
in the N-terminal domains of ACA2 (Harper et al., 1998), ACA4 (Geisler
et al., 2000b), and ACA8 (Bonza et al., 2000). In these pumps, the N
terminus is likely to form an autoinhibitory regulatory domain (Geisler
et al., 2000b; Hwang et al., 2000a, 2000b).
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P3A ATPases |
P3A ATPases encompass a subfamily of plasma
membrane H+-ATPases only found in plants and
fungi. This group consists of 11 very closely related members being at
least 66% identical and a truncated gene, which might be a pseudogene
or have alternative functions (AHA12; see below). The
P3A ATPases have recently been reviewed (Palmgren, 2001). They all have the same structure with a prolonged C-terminal regulatory domain comprising a 14-3-3 binding site and a
phosphorylation site at the penultimate Thr residue. The two most
expressed P-type ATPases in Arabidopsis can be found in this family.
Thus, AHA1 and AHA2 are five to eight times more abundant than any of
the other proteins as based on number of ESTs identified for each
(Table I).
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P4 ATPases |
Twelve proteins from Arabidopsis are members of the large
subfamily of P4 ATPases, which includes a
substantial number of the P-type ATPases found in other eukaryotic
organisms (Table II). A bioinformatic study of the
P4 ATPases in Arabidopsis has recently been
published (Gomes et al., 2000). They form two closely related clusters
(pumps being >75% identical in each cluster) consisting of ALA4
through ALA7 and ALA9 through ALA12, with ALA8 placed in between the
clusters and ALA1, ALA2, and ALA3 more distant from the other subfamily members.
Two of the Arabidopsis P4 ATPases have been
cloned (ALA1, Gomes et al., 2000; ALA2, M.K.
Jakobsen, personal communication), but only ALA1 has been
characterized, and it was demonstrated that this gene is involved in
cold tolerance of Arabidopsis plants (Gomes et al., 2000). ALA1 (Gomes
et al., 2000), bovine ATPase II (Tang et al., 1996), and yeast DRS2
(Tang et al., 1996; Gomes et al., 2000), all belonging to the
P4 ATPase cluster, have been implicated in
flipping of aminophospholipids. Studies with four recombinant isoforms
of bovine ATPase II, all P4 pumps, revealed that
the potential substrate phosphatidyl-Ser is essential for the
dephosphorylation of the phosphorylated reaction cycle intermediate and
for continuation of its catalytic cycle (Ding et al., 2000). Dephosphorylation of P-type ATPases is normally triggered by the transported species and results in the conformational change that is
associated with transport (Møller et al., 1996). The human P4 ATPase FIC1 (Bull et al., 1998) is involved in
the transport of conjugated bile acids. Overexpression of yeast NEO1
(Prezant et al., 1996), which resembles DRS2, results in resistance to the aminoglucoside neomycin by a mechanism that is not understood.
From the above it appears that P4 ATPases
are involved in the transport of relatively large amphipathic
compounds. However, it is not known whether this is a direct or
indirect effect of P4 ATPases. Thus, the
transport capabilities of none of these pumps have been characterized
following their purification and reconstitution in an artificial
membrane. It should be noted that a phenotype of drs2 cells
is sensitivity toward Zn2+ and
Co2+ (Siegmund et al., 1998). Whether this
reflects a role for this and other P4 ATPases in
the transport of transition metals is not known. Disruption of
DRS2 also results in a defect of ribosome assembly, a
process known to be dependent upon Zn2+ (Tal,
1969).
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P5 ATPases |
There is only a single member of P5 ATPases
in Arabidopsis. The substrate specificity of this subfamily, found only
in eukaryotes, is unknown because none of its members have been
characterized biochemically.
Deletion of the two P5 ATPases in the yeast
S. cerevisiae are nonlethal, but deletion of SPF1
leads to glycosylation defects (Suzuki and Shimma, 1999) and deficient
ubiquitin-dependent degradation of an enzyme in the mevalonate
biosynthetic pathway (Cronin et al., 2000). The latter phenotype could
be partially reversed by adding high Ca2+ to the
medium. Therefore, it was suggested that SPF1 could be a
Ca2+-ATPase important for maintaining
Ca2+ homeostasis in a membrane system in the
secretory pathway (Cronin et al., 2000). The spf1 phenotype
partially mimics the phenotype of a yeast strain deleted for the
secretory pathway Ca2+/Mn2+
ATPase PMR1 because the degradation of a protein, misfolded
caboxypeptidase protein Y, was affected in the pmr1 strain
(Dürr et al., 1998). However, ubiquitin-dependent degradation
is not affected in this strain. If SPF1 is a Ca2+
ATPase, a novel calcium-binding site must be found in the
P5 ATPases because only one of the residues
important for coordination of Ca2+ ions in
SERCA1a, a P2A Ca2+-ATPase
of which the structure has been solved at 2.6-Å resolution (Toyoshima
et al., 2000), are conserved in P5 ATPases (Fig.
3).
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Figure 3.
Alignment of Ca2+ binding
residues in TM segments from different P-type ATPases. An
alignment of the full length Arabidopsis ATPases was performed using
T-COFFEE (Notredame et al., 2000). The TM segments 4-6 and 8 were
extracted from the alignment. The overall alignment was reliable for TM
segments 4-6, whereas the alignment of TM 8 is more dubious as the
similarity between the P2A,
P4 and P5 ATPases is low in
this region. The alignment includes the P2A
ATPase SERCA1a from rabbit (ATC1) the Ca2+
ATPases PMR1 (P2A) and PCA1
(P2B) from S. cerevisiae, the
P2D Ca2+ ATPase CTA3 from
Schizosaccharomyces pombe as well as a selection of ATPases
from Arabidopsis. Residues involved in coordination of
Ca2+ in the two Ca2+
binding sites (Site I and Site II) found in the 2.6 Å crystal
structure of SERCA1a (Toyoshima et al., 2000) are marked with 1 and 2, respectively. The position marked X is a residue involved in
coordination of both Ca2+ ions. Residues with
hydrophobic side chains in TM 4 contribute with backbone carbonyl
oxygens.
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SODIUM TRANSPORT IN ARABIDOPSIS |
Na+ is excluded from the cytoplasm of most
living cells because it generates osmotic stress and has specific toxic
effects (Bohnert et al., 1995). Animals and fungi have
Na+-/K+-ATPases
(P2C ATPases) and
Na+-ATPases (P2D ATPases),
respectively, that carry out this task (Axelsen and Palmgren, 1998). No
Arabidopsis P-type ATPase group in a phylogenetic tree together with
P2C or P2D ATPases.
This would suggest that Arabidopsis is not equipped with pumps that can
transport Na+.
Plant cells are more Na+ sensitive than animal
and fungal cells, except in some species adapted to
Na+-rich environments. Exclusion of
Na+ from the cytoplasm of Arabidopsis is probably
mediated by Na+/H+
antiporters in two membrane systems: the plasma membrane and the
vacuolar membrane. The gene SOS1 in Arabidopsis may encode a
plasma membrane antiporter (Shi et al., 2000), whereas NHX1 may encode a vacuolar antiporter (Apse et al., 1999; Gaxiola et al.,
1999). Arabidopsis harbors at least three evident
Na+/H+ antiporters similar
to SOS1, and four similar to vacuolar antiporters.
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P-TYPE ATPases WITH ALTERNATIVE ROLES |
The analysis of the Arabidopsis genome resulted in the
identification of a P3A ATPase (AHA12;
At4g11730p) lacking a conserved domain involved in ATP binding. In
addition, the complete C-terminal autoinhibitory domain is missing and
is replaced by 50 amino acid residues having no similarity to other
P3A ATPases (see Table I). Besides these peculiar
features, the protein closely resembles other Arabidopsis
P3A ATPases (72% identity to AHA3) and the
transmembrane regions are intact, suggesting that
H+ binding can occur. This raises the question of
whether AHA12 is a pseudogene (it is not represented by an
EST) or whether it is an example of a gene coding for an ATPase like
protein with an alternative function.
P-type ATPase-like proteins lacking parts of the universally conserved
domains and/or TM segments have been characterized in animal systems.
One example is a P4 ATPase like protein from rabbit lacking TM segment 4, which is universally conserved in the
P-type ATPase family. The protein is situated in the inner nuclear
membrane and was identified because of its ability to bind RING
finger domains of a RUSH transcription factor (Mansharamani et al.,
2001). Another example is the splice variants of the human P1B ATPases Menkes and Wilson disease proteins,
which lack several universally conserved domains as well as either two
or eight of the transmembrane segments, resulting in the splice
variants being cytosolic (Yang et al., 1997; Reddy and Harris, 1998;
Reddy et al., 2000). The shortest splice variant of the Menkes protein only codes for a 103-amino acid protein, which contains a nuclear targeting signal, a single HMA domain, and a short C-terminal domain. A
final example is the protein identified in the genome of the archaea
M. jannaschii resembling the large cytoplasmic domain of
P-type ATPases (Ogawa et al., 2000). It has been demonstrated that this
soluble ATPase shows ATPase activity, autophosphorylation, and
inhibition by vanadate (Ogawa et al., 2000).
The functions of the partially deleted isoforms found in animals are
unknown, but it has been suggested (Reddy et al., 2000) that shortened
P1B ATPases could be involved in regulation
of Cu2+-ATPase activity,
Cu2+ sensing, or in directing
Cu2+ to the nucleus. These findings, however, do
not lead to an evident suggestion for the function of AHA12.
Two other genes in the Arabidopsis genome with homology to P-type
ATPases (At2g23280 and At5g53010) are likely to represent pseudogenes.
The first half of At2g23280 is very similar to 100 amino acids of the
large cytoplasmic domain of P1B ATPases, whereas the second half has no resemblance to P-type ATPases. At5g53010 is
similar to P2A ATPases, but is lacking the first
and last 100 amino acids, and it is also lacking or has mutations in
most of the universally conserved residues. It is most notable that in the large cytoplasmic domain encompassing the phosphorylation and ATP
binding sites, the entire DKTGTLT motif is missing and the TGD and
GDGND motifs have been distorted. The rudimentary structure, the
lack of conserved regions, and the fact that neither of the two
proteins in question are supported by ESTs are indicatives of a
pseudogene nature of these genes.
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WHY ARE THERE SO MANY P-TYPE ATPases IN ARABIDOPSIS? |
Genetic redundancy in Arabidopsis is the result of (a) a
polyploidization event in an ancestral plant around 150 million years ago, and (b) a number of local gene duplications resulting in the
generation of tandem gene arrays (The Arabidopsis Genome Initiative, 2000). Such events might partly explain the high number of P-type ATPase genes in Arabidopsis. However, the various P-type ATPases subfamilies evolved well before the evolution of plants (Axelsen and Palmgren, 1998). Thus, the divergence of
P1 and P2 ATPases occurred before the split between bacteria, archaea, and eukarya, and the evolution of P4 and
P5 ATPases occurred before the separation of
plants from fungi and animals.
Another reason for the large number of P-type ATPases in Arabidopsis
could be the lack of alternative splicing events taking place in
plants. Thus, protein diversity in animals can be obtained by
alternative splicing of identical genes. A SWISS-PROT database search
revealed that documented splice variants found in the human P-type
ATPases produce at least 80 different P-type ATPase protein species
(data not shown).
Plants are immobile and thus have to adapt to more varying conditions
such as temperature and availability of water and nutrition, and
furthermore distribute messages of the changes of these conditions. Perhaps one parameter to achieve this ability of adaptation is to have
a large variety of isoforms within each protein family, in this way
enabling the plant to quickly fine-tune its response to the conditions
given at any time.
In different subfamilies of P-type ATPases, isoform divergency might
serve different purposes. The high number of P3
ATPases in Arabidopsis and in other plants might be a means to
facilitate expression of a sufficient amount of
H+-ATPases in different cells and tissues at
different stages of development (Oufattole et al., 2000; Palmgren,
2001). The evidence available so far supports the notion that all
P3 ATPases are expressed in the plasma membrane
(DeWitt et al., 1996). However, different Arabidopsis
Ca2+-ATPases appear to be expressed in different
cellular membranes. Here they serve a role pumping
Ca2+ into intracellular compartments in addition
to extruding Ca2+ from the cell (Geisler et al.,
2000a). Some organelles, such as the endoplasmic reticulum, even harbor
more than one Ca2+-ATPase (Hong et al., 1999). By
analogy, one might speculate that P1B ATPases,
depending on their membrane location, could be involved in both
extrusion and sequestration of heavy metals.
Ca2+-ATPases and
Ca2+/H+ antiporters in
concert keep cytoplasmic calcium concentrations in the sub-micromolar
range, which is a prerequisite for Ca2+ signaling
(Sanders et al., 1999; Sze et al., 2000). It has been shown
recently that a mutation in DET3, which encodes a subunit of
an Arabidopsis V-type H+ pump that supplies the
driving force for vacuolar membrane
Ca2+/H+
antiporter(s), results in specific distortions in signal-induced Ca2+ oscillations in Arabidopsis stomatal guard
cells (Allen et al., 2000). Reverse genetic approaches might prove
valuable to solve the question of whether individual
Ca2+-ATPase isoforms might play a role in
encoding specificity in plant Ca2+ signaling.
| |
CONCLUSIONS AND FUTURE PROSPECTS |
The complete inventory of Arabidopsis P-type ATPases has
revealed a surprising large number of transporters belonging to this family. At one level, the complexity of P-type pumps reflects the
various ion specificities these transporters are equipped with. At a
second level, different isoforms are expressed in a tissue- and
cell-type-specific manner. At a third level, isoforms belonging to the
same subfamily are expressed in different membranes in the cell.
Some important directions for future research include the assignment of
transport specificities to P4 and
P5 ATPases, establishing the structural basis for
regulation of P-type ATPases by terminal autoinhibitory domains, and
assigning physiological roles to the various P-type pumps. We can
expect rapid advances in our understanding of the function of P-type
pumps with the combination of physiological and molecular genetic
approaches in the coming years. Reporter gene analyses (Haseloff, 1999;
Moriau et al., 1999) and DNA microarray technology (Schena et al.,
1995) will be employed on a large scale to study gene expression as a
function of space, time, and environmental conditions. In the different
subfamilies, knockout mutants for all members will be isolated and
multiple knockouts will be generated by crossing these lines (Young et
al., 2001). The phenotypes of knockout lines will be studied carefully
under all thinkable conditions. In this context, it will be of
particular interest to learn whether additional roles for P-type pumps
can be identified.
| |
FOOTNOTES |
Received February 26, 2001; returned for revision March 22, 2001; accepted April 2, 2001.
1
The work in the laboratory of M.G.P. was
supported by the European Union's Biotechnology Program and by the
Human Frontier Science Program Organization.
*
Corresponding author; e-mail palmgren{at}biobase.dk; fax
45-3528-3365.
| |
LITERATURE CITED |
-
Allen GJ, Chu SP, Schumacher K, Shimazaki CT, Vafeados D, Kemper A, Hawke SD, Tallman G, Tsien RY, Harper JF
(2000)
Alteration of stimulus-specific guard cell calcium oscillations and stomatal closing in Arabidopsis det3 mutant.
Science
289: 2338-2342[Abstract/Free Full Text]
-
Apse MP, Aharon GS, Snedden WA, Blumwald E
(1999)
Salt tolerance conferred by overexpression of a vacuolar Na+/H+ antiport in Arabidopsis.
Science
285: 1256-1258[Abstract/Free Full Text]
-
Axelsen KB, Palmgren MG
(1998)
Evolution of substrate specificities in the P-type ATPase superfamily.
J Mol Evol
46: 84-101[CrossRef][Web of Science][Medline]
-
Beard SJ, Hashim R, Membrillo-Hernandez J, Hughes MN, Poole RK
(1997)
Zinc(II) tolerance in Escherichia coli K-12: evidence that the zntA gene (o732) encodes a cation transport ATPase.
Mol Microbiol
25: 883-891[CrossRef][Web of Science][Medline]
-
Bohnert HJ, Nelson DE, Jensen RG
(1995)
Adaptation to environmental stresses.
Plant Cell
7: 1099-1111[CrossRef][Web of Science][Medline]
-
Bonza MC, Morandini P, Luoni L, Geisler M, Palmgren MG, De Michelis MI
(2000)
At-ACA8 encodes a plasma membrane-localized calcium-ATPase of Arabidopsis with a calmodulin-binding domain at the N terminus.
Plant Physiol
123: 1495-1506[Abstract/Free Full Text]
-
Bull LN, van Eijk MJ, Pawlikowska L, DeYoung JA, Juijn JA, Liao M, Klomp LW, Lomri N, Berger R, Scharschmidt BF
(1998)
A gene encoding a P-type ATPase mutated in two forms of hereditary cholestasis.
Nat Genet
18: 219-224[CrossRef][Web of Science][Medline]
-
Bull PC, Cox DW
(1994)
Wilson disease and Menkes disease: new handles on heavy-metal transport.
Trends Genet
10: 246-252[CrossRef][Web of Science][Medline]
-
Cronin SR, Khoury A, Ferry DK, Hampton RY
(2000)
Regulation of HMG-CoA reductase degradation requires the P-type ATPase Cod1p/Spf1p.
J Cell Biol
148: 915-924[Abstract/Free Full Text]
-
Curie C, Alonso JM, Le Jean M, Ecker JR, Briat J-F
(2000)
Involvement of NRAMP1 from Arabidopsis thaliana in iron transport.
Biochem J
347: 749-755
-
Danks DM, Campbell PE, Stevens BJ, Mayne V, Cartwright E
(1972)
Menkes' kinky hair syndrome: an inherited defect in copper absorption with widespread effects.
Pediatrics
50: 188-201[Abstract/Free Full Text]
-
DeWitt ND, Hong B, Sussman MR, Harper JF
(1996)
Targeting of two Arabidopsis H+-ATPase isoforms to the plasma membrane.
Plant Physiol
112: 833-844[Abstract]
-
Ding J, Wu Z, Crider BP, Ma Y, Li X, Slaughter C, Gong L, Xie XS
(2000)
Identification and functional expression of four isoforms of ATPase II, the putative aminophospholipid translocase: effect of isoform variation on the ATPase activity and phospholipid specificity.
J Biol Chem
275: 23378-23386[Abstract/Free Full Text]
-
Dürr G, Strayle J, Plemper R, Elbs S, Klee SK, Catty P, Wolf DH, Rudolph HK
(1998)
The medial-Golgi ion pump Pmr1 supplies the yeast secretory pathway with Ca2+ and Mn2+ required for glycosylation, sorting, and endoplasmic reticulum-associated protein degradation.
Mol Biol Cell
9: 1149-1162[Abstract/Free Full Text]
-
Eide D, Broderius M, Fett J, Guerinot ML
(1996)
A novel iron-regulated metal transporter from plants identified by functional expression in yeast.
Proc Natl Acad Sci USA
93: 5624-5628[Abstract/Free Full Text]
-
Evans DE, Williams LE
(1998)
P-type calcium ATPases in higher plants: biochemical, molecular and functional properties.
Biochim Biophys Acta
1376: 1-25[Medline]
-
Felsenstein J
(1989)
PHYLIP: phylogeny inference package (version 32).
Cladistics
5: 164-166
-
Gaxiola RA, Rao R, Sherman A, Grisafi P, Alper SL, Fink GR
(1999)
The Arabidopsis thaliana proton transporters, AtNhx1 and Avp1, can function in cation detoxification in yeast.
Proc Natl Acad Sci USA
96: 1480-1485[Abstract/Free Full Text]
-
Geisler M, Axelsen KB, Harper JF, Palmgren MG
(2000a)
Molecular aspects of higher plant P-type Ca2+-ATPases.
Biochim Biophys Acta
1465: 52-78[Medline]
-
Geisler M, Frangne N, Gomes E, Martinoia E, Palmgren MG
(2000b)
The ACA4 gene of Arabidopis encodes a vacuolar membrane calcium pump that improves salt tolerance in yeast.
Plant Physiol
124: 1814-1827[Abstract/Free Full Text]
-
Gomes E, Jakobsen MK, Axelsen KB, Geisler M, Palmgren MG
(2000)
Chilling tolerance in Arabidopsis involves ALA1, a member of a new family of putative aminophospholipid translocases.
Plant Cell
12: 2441-2454[Abstract/Free Full Text]
-
Grotz N, Fox T, Connolly E, Park W, Guerinot ML, Eide D
(1998)
Identification of a family of zinc transporter genes from Arabidopsis that respond to zinc deficiency.
Proc Natl Acad Sci USA
95: 7220-7224[Abstract/Free Full Text]
-
Guerinot ML
(2000)
The ZIP family of metal transporters.
Biochim Biophys Acta
1465: 190-198[Medline]
-
Harper JF, Hong B, Hwang I, Guo HQ, Stoddard R, Huang JF, Palmgren MG, Sze H
(1998)
A novel calmodulin-regulated Ca2+-ATPase (ACA2) from Arabidopsis with an N-terminal autoinhibitory domain.
J Biol Chem
273: 1099-1106[Abstract/Free Full Text]
-
Haseloff J
(1999)
GFP variants for multispectral imaging of living cells.
Methods Cell Biol.
58: 139-151[Web of Science][Medline]
-
Hirayama T, Kieber JJ, Hirayama N, Kogan M, Guzman P, Nourizadeh S, Alonso JM, Dailey WP, Dancis A, Ecker JR
(1999)
RESPONSIVE-TO-ANTAGONIST1, a Menkes/Wilson disease-related copper transporter, is required for ethylene signaling in Arabidopsis.
Cell
97: 383-393[CrossRef][Web of Science][Medline]
-
Hong B, Ichida A, Wang Y, Gens JS, Pickard BG, Harper JF
(1999)
Identification of a calmodulin-regulated Ca2+-ATPase in the endoplasmic reticulum.
Plant Physiol
119: 1165-1176[Abstract/Free Full Text]
-
Huang L, Berkelman T, Franklin AE, Hoffman NE
(1993)
Characterization of a gene encoding a Ca2+-ATPase-like protein in the plastid envelope.
Proc Natl Acad Sci USA
90: 10066-10070[Abstract/Free Full Text]
-
Hwang I, Harper JF, Liang F, Sze H
(2000a)
Calmodulin activation of an endoplasmic reticulum-located calcium pump involves an interaction with the N-terminal autoinhibitory domain.
Plant Physiol
122: 157-168[Abstract/Free Full Text]
-
Hwang I, Sze H, Harper JF
(2000b)
A calcium-dependent protein kinase can inhibit a calmodulin-stimulated Ca2+ pump (ACA2) located in the endoplasmic reticulum of Arabidopsis.
Proc Natl Acad Sci USA
97: 6224-6229[Abstract/Free Full Text]
-
Korshunova YO, Eide D, Clark WG, Guerinot ML, Pakrasi HB
(1999)
The IRT1 protein from Arabidopsis thaliana is a metal transporter with a broad substrate range.
Plant Mol Biol
40: 37-44[CrossRef][Web of Science][Medline]
-
Lapinskas PJ, Cunningham KW, Liu XF, Fink GR, Culotta VC
(1995)
Mutations in PMR1 suppress oxidative damage in yeast cells lacking superoxide dismutase.
Mol Cell Biol
15: 1382-1388[Abstract]
-
Liang F, Cunningham KW, Harper JF, Sze H
(1997)
ECA1 complements yeast mutants defective in Ca2+ pumps and encodes an endoplasmic reticulum-type Ca2+-ATPase in Arabidopsis thaliana.
Proc Natl Acad Sci USA
94: 8579-8584[Abstract/Free Full Text]
-
Malmström S, Askerlund P, Palmgren MG
(1997)
A calmodulin-stimulated Ca2+-ATPase from plant vacuolar membranes with a putative regulatory domain at its N-terminus.
FEBS Lett
400: 324-328[CrossRef][Medline]
-
Mansharamani M, Hewetson A, Chilton BS
(2001)
Cloning and characterization of an atypical Type IV P-type ATPase that binds to the RING motif of RUSH transcription factors.
J Biol Chem.
276: 3641-3649[Abstract/Free Full Text]
-
Mäser P, Thomine S, Schroeder JI, Hirschi K, Ward J, Sze H,
Amtmann A, Maathuis FJM, Talke IN, Sanders D et al. (2001)
Phylogenetic relationships within cation-transporter families of
Arabidopsis. Plant Physiol (in press)
-
Møller JV, Juul B, Le Maire M
(1996)
Structural organization, ion transport, and energy transduction of P-type ATPases.
Biochim Biophys Acta
1286: 1-51[Medline]
-
Moriau L, Michelet B, Bogaerts P, Lambert L, Michel A, Oufattole M, Boutry M
(1999)
Expression analysis of two gene subfamilies encoding the plasma membrane H+-ATPase in Nicotiana plumbaginifolia reveals the major transport functions of this enzyme.
Plant J
19: 31-41[CrossRef][Web of Science][Medline]
-
Notredame C, Higgins DG, Heringa J
(2000)
T-Coffee: A novel method for fast and accurate multiple sequence alignment.
J Mol Biol
302: 205-217[CrossRef][Web of Science][Medline]
-
Ogawa H, Haga T, Toyoshima C
(2000)
Soluble P-type ATPase from an archaeon, Methanococcus jannaschii.
FEBS Lett
471: 99-102[CrossRef][Medline]
-
Oufattole M, Arango M, Boutry M
(2000)
Identification and expression of three new Nicotiana plumbaginifolia genes which encode isoforms of a plasma-membrane H+-ATPase, and one of which is induced by mechanical stress.
Planta
210: 715-722[CrossRef][Web of Science][Medline]
-
Palmgren MG
(2001)
Plasma membrane H+-ATPases: Powerhouses for nutrient uptake.
Annu Rev Plant Physiol Plant Mol Biol
52: 817-845[CrossRef][Web of Science][Medline]
-
Palmgren MG, Harper JF
(1999)
Pumping with plant P-type ATPases.
J Exp Bot
50: 883-893[Abstract]
-
Pittman JK, Mills RF, O'Connor CD, Williams LE
(1999)
Two additional type IIA Ca2+-ATPases are expressed in Arabidopsis thaliana: evidence that type IIA sub-groups exist.
Gene
236: 137-147[CrossRef][Web of Science][Medline]
-
Prezant TR, Chaltraw WE, Fischel-Ghodsian N
(1996)
Identification of an overexpressed yeast gene which prevents aminoglycoside toxicity.
Microbiology
142: 3407-3414[Abstract/Free Full Text]
-
Reddy MCM, Harris ED
(1998)
Multiple transcripts coding for the Menkes gene: evidence for alternative splicing of Menkes mRNA.
Biochem J
334: 71-77
-
Reddy MCM, Majumdar S, Harris ED
(2000)
Evidence for a Menkes-like protein with a nuclear targeting sequence.
Biochem J
350: 855-863
-
Rensing C, Mitra B, Rosen BP
(1997)
The zntA gene ofEscherichia coli encodes a Zn(II)-translocating P-type ATPase.
Proc Natl Acad Sci USA
94: 14326-14331[Abstract/Free Full Text]
-
Rensing C, Sun Y, Mitra B, Rosen BP
(1998)
Pb(II)-translocating P-type ATPases.
J Biol Chem
273: 32614-32617[Abstract/Free Full Text]
-
Sanders D, Brownlee C, Harper JF
(1999)
Communicating with calcium.
Plant Cell
11: 691-706[Free Full Text]
-
Schena M, Shalon D, Davis RW, Brown PO
(1995)
Quantitative monitoring of gene expression patterns with a complementary DNA microarray.
Science
270: 467-470[Abstract/Free Full Text]
-
Serrano R
(1989)
Structure and function of plasma membrane ATPase.
Annu Rev Plant Physiol Plant Mol Biol
40: 61-94[CrossRef][Web of Science]
-
Shi H, Ishitani M, Kim C, Zhu J-K
(2000)
The Arabidopsis thaliana salt tolerance gene SOS1 encodes a putative Na+/H+ antiporter.
Proc Natl Acad Sci USA
97: 6896-6901[Abstract/Free Full Text]
-
Siegmund A, Grant A, Angeletti C, Malone L, Nichols JW, Rudolph HK
(1998)
Loss of Drs2p does not abolish transfer of fluorescence-labeled phospholipids across the plasma membrane of Saccharomyces cerevisiae.
J Biol Chem
273: 34399-34405[Abstract/Free Full Text]
-
Solioz M, Odermatt A
(1995)
Copper and silver transport by CopB-ATPase in membrane vesicles of Enterococcus hirae.
J Biol Chem
270: 9217-9221[Abstract/Free Full Text]
-
Solioz M, Vulpe C
(1996)
CPx-type ATPases: a class of P-type ATPases that pump heavy metals.
Trends Biochem Sci
21: 237-241[CrossRef][Web of Science][Medline]
-
Suzuki C, Shimma YI
(1999)
P-type ATPase spf1 mutants show a novel resistance mechanism for the killer toxin SMKT.
Mol Microbiol
32: 813-823[CrossRef][Web of Science][Medline]
-
Sze H, Liang F, Hwang I, Curran A, Harper JF
(2000)
Diversity and regulation of plant Ca2+ pumps: insights from expression in yeast.
Annu Rev Plant Phys Plant Mol Biol
51: 433-462[CrossRef][Web of Science][Medline]
-
Tal M
(1969)
Metal ions and ribosomal conformation.
Biochim Biophys Acta
195: 76-86[Medline]
-
Tang X, Halleck MS, Schlegel RA, Williamson P
(1996)
A subfamily of P-type ATPases with aminophospholipid transporting activity.
Science
272: 1495-1497[Abstract]
-
The Arabidopsis Genome Initiative
(2000)
Analysis of the genome sequence of the flowering plant Arabidopsis thaliana.
Nature
408: 796-815[CrossRef][Medline]
-
Thelwell C, Robinson NJ, Turner-Cavet JS
(1998)
An SmtB-like repressor from Synechocystis PCC 6803 regulates a zinc exporter.
Proc Natl Acad Sci USA
95: 10728-10733[Abstract/Free Full Text]
-
Thomine S, Wang R, Ward JM, Crawford NM, Schroeder JI
(2000)
Cadmium and iron transport by members of a plant metal transporter family in Arabidopsis with homology to Nramp genes.
Proc Natl Acad Sci USA
97: 4991-4996[Abstract/Free Full Text]
-
Toyoshima C, Nakasako M, Nomura H, Ogawa H
(2000)
Crystal structure of the calcium pump of sarcoplasmic reticulum at 2.6 Å resolution.
Nature
405: 647-655[CrossRef][Medline]
-
Williams LE, Pittman JK, Hall JL
(2000)
Emerging mechanisms for heavy metal transport in plants.
Biochim Biophys Acta
1465: 104-126[Medline]
-
Woeste KE, Kieber JJ
(2000)
A strong loss-of-function mutation in RAN1 results in constitutive activation of the ethylene response pathway as well as a rosette-lethal phenotype.
Plant Cell
12: 443-455[Abstract/Free Full Text]
-
Young JC, Krysan PJ, Sussman MR
(2001)
Efficient screening of Arabidopsis T-DNA insertion lines using degenerate primers.
Plant Physiol
125: 513-518[Abstract/Free Full Text]
-
Yang XL, Miura N, Kawarada Y, Terada K, Petrukhin K, Gilliam T, Sugiyama T
(1997)
Two forms of Wilson disease protein produced by alternative splicing are localized in distinct cellular compartments.
Biochem J
326: 897-902
-
Yuan DS, Stearman R, Dancis A, Dunn T, Beeler T, Klausner RD
(1995)
The Menkes/Wilson disease gene homologue in yeast provides copper to a ceruloplasmin-like oxidase required for iron uptake.
Proc Natl Acad Sci USA
92: 2632-2636[Abstract/Free Full Text]
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The Potassium-Dependent Transcriptome of Arabidopsis Reveals a Prominent Role of Jasmonic Acid in Nutrient Signaling
Plant Physiology,
September 1, 2004;
136(1):
2556 - 2576.
[Abstract]
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D. Hussain, M. J. Haydon, Y. Wang, E. Wong, S. M. Sherson, J. Young, J. Camakaris, J. F. Harper, and C. S. Cobbett
P-Type ATPase Heavy Metal Transporters with Roles in Essential Zinc Homeostasis in Arabidopsis
PLANT CELL,
May 1, 2004;
16(5):
1327 - 1339.
[Abstract]
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J. M. Coombs and T. Barkay
Molecular Evidence for the Evolution of Metal Homeostasis Genes by Lateral Gene Transfer in Bacteria from the Deep Terrestrial Subsurface
Appl. Envir. Microbiol.,
March 1, 2004;
70(3):
1698 - 1707.
[Abstract]
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F. J. Perez-Victoria, F. Gamarro, M. Ouellette, and S. Castanys
Functional Cloning of the Miltefosine Transporter: A NOVEL P-TYPE PHOSPHOLIPID TRANSLOCASE FROM LEISHMANIA INVOLVED IN DRUG RESISTANCE
J. Biol. Chem.,
December 12, 2003;
278(50):
49965 - 49971.
[Abstract]
[Full Text]
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J. L. Hall and L. E. Williams
Transition metal transporters in plants
J. Exp. Bot.,
December 1, 2003;
54(393):
2601 - 2613.
[Abstract]
[Full Text]
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Z. Hou and B. Mitra
The Metal Specificity and Selectivity of ZntA from Escherichia coli Using the Acylphosphate Intermediate
J. Biol. Chem.,
August 1, 2003;
278(31):
28455 - 28461.
[Abstract]
[Full Text]
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I. Baxter, J. Tchieu, M. R. Sussman, M. Boutry, M. G. Palmgren, M. Gribskov, J. F. Harper, and K. B. Axelsen
Genomic Comparison of P-Type ATPase Ion Pumps in Arabidopsis and Rice
Plant Physiology,
June 1, 2003;
132(2):
618 - 628.
[Abstract]
[Full Text]
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T. Shikanai, P. Muller-Moule, Y. Munekage, K. K. Niyogi, and M. Pilon
PAA1, a P-Type ATPase of Arabidopsis, Functions in Copper Transport in Chloroplasts
PLANT CELL,
June 1, 2003;
15(6):
1333 - 1346.
[Abstract]
[Full Text]
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N.-H. Cheng, J. K. Pittman, B. J. Barkla, T. Shigaki, and K. D. Hirschi
The Arabidopsis cax1 Mutant Exhibits Impaired Ion Homeostasis, Development, and Hormonal Responses and Reveals Interplay among Vacuolar Transporters
PLANT CELL,
February 1, 2003;
15(2):
347 - 364.
[Abstract]
[Full Text]
[PDF]
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L. Tong, S. Nakashima, M. Shibasaka, M. Katsuhara, and K. Kasamo
A Novel Histidine-Rich CPx-ATPase from the Filamentous Cyanobacterium Oscillatoria brevis Related to Multiple-Heavy-Metal Cotolerance
J. Bacteriol.,
September 15, 2002;
184(18):
5027 - 5035.
[Abstract]
[Full Text]
[PDF]
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Z. Wu, F. Liang, B. Hong, J. C. Young, M. R. Sussman, J. F. Harper, and H. Sze
An Endoplasmic Reticulum-Bound Ca2+/Mn2+ Pump, ECA1, Supports Plant Growth and Confers Tolerance to Mn2+ Stress
Plant Physiology,
September 1, 2002;
130(1):
128 - 137.
[Abstract]
[Full Text]
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V. R. Ordenes, F. C. Reyes, D. Wolff, and A. Orellana
A Thapsigargin-Sensitive Ca2+ Pump Is Present in the Pea Golgi Apparatus Membrane
Plant Physiology,
August 1, 2002;
129(4):
1820 - 1828.
[Abstract]
[Full Text]
[PDF]
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S. R. Cronin, R. Rao, and R. Y. Hampton
Cod1p/Spf1p is a P-type ATPase involved in ER function and Ca2+ homeostasis
J. Cell Biol.,
June 10, 2002;
157(6):
1017 - 1028.
[Abstract]
[Full Text]
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A. L. O. Facanha, H. Appelgren, M. Tabish, L. Okorokov, and K. Ekwall
The endoplasmic reticulum cation P-type ATPase Cta4p is required for control of cell shape and microtubule dynamics
J. Cell Biol.,
June 10, 2002;
157(6):
1029 - 1040.
[Abstract]
[Full Text]
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D. Sanders, J. Pelloux, C. Brownlee, and J. F. Harper
Calcium at the Crossroads of Signaling
PLANT CELL,
May 1, 2002;
14(90001):
S401 - 417.
[Full Text]
[PDF]
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G. Grass, M. D. Wong, B. P. Rosen, R. L. Smith, and C. Rensing
ZupT Is a Zn(II) Uptake System in Escherichia coli
J. Bacteriol.,
February 1, 2002;
184(3):
864 - 866.
[Abstract]
[Full Text]
[PDF]
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P. Maser, S. Thomine, J. I. Schroeder, J. M. Ward, K. Hirschi, H. Sze, I. N. Talke, A. Amtmann, F. J.M. Maathuis, D. Sanders, et al.
Phylogenetic Relationships within Cation Transporter Families of Arabidopsis
Plant Physiology,
August 1, 2001;
126(4):
1646 - 1667.
[Abstract]
[Full Text]
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Z.-j. Hou, S. Narindrasorasak, B. Bhushan, B. Sarkar, and B. Mitra
Functional Analysis of Chimeric Proteins of the Wilson Cu(I)-ATPase (ATP7B) and ZntA, a Pb(II)/Zn(II)/Cd(II)-ATPase from Escherichia coli
J. Biol. Chem.,
October 26, 2001;
276(44):
40858 - 40863.
[Abstract]
[Full Text]
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TOP
ABSTRACT
INTRODUCTION
