Structure-Function Relations of Interactions between Na,K-ATPase, the
Subunit, and Corticosteroid Hormone-induced Factor*
Moshit Lindzen,
Roman Aizman,
Yael Lifshitz,
Irina Lubarski,
Steven J. D. Karlish
and
Haim Garty
From the
Department of Biological Chemistry, The Weizmann Institute of Science, Rehovot 76100, Israel
Received for publication, December 30, 2002
, and in revised form, February 14, 2003.
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ABSTRACT
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Corticosteroid hormone-induced factor (CHIF) and the
subunit of the Na,K-ATPase (
) are two members of the FXYD family whose function has been elucidated recently. CHIF and
interact with the Na+ pump and alter its kinetic properties, in different ways, which appear to serve their specific physiological roles. Although functional interactions with the Na,K-ATPase have been clearly demonstrated, it is not known which domains and which residues interact with the
and/or
subunits and affect the pump kinetics. The current study provides the first systematic analysis of structure-function relations of CHIF and
. It is demonstrated that the stability of detergent-solubilized complexes of CHIF and
with
and/or
subunits is determined by the trans-membrane segments, especially three residues that may be involved in hydrophobic interactions. The transmembrane segments also determine the opposite effects of CHIF and
on the Na+ affinity of the pump, but the amino acids involved in this functional effect are different from those responsible for stable interactions with
.
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INTRODUCTION
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FXYD is a recently identified gene family involved in the regulation of ion transport (1). The seven members of this group code for short single-span membrane proteins (<100 amino acids), named after the invariant motif FXYD, located in their extracellular domains. The
subunit of Na,K-ATPase (
, FXYD2) is known to associate with the 
complex and modulate pump kinetics (2, 3, 4, 5). Recent studies using transfected cells and Xenopus oocytes have established that at least three other FXYD proteins, phospholemman (FXYD1) (6), CHIF1 (FXYD2) (7, 8), and FXYD7 (9) interact with the pump and alter its kinetic properties. Each of these proteins has specific but different effects on the pump kinetics and also a different tissue distribution. Thus, the emerging picture is that these and probably all other FXYD proteins are tissue-specific subunits or regulators of the Na,K-ATPase. They provide the means to alter pump properties in specific target tissues, cell types, or physiological states without affecting it elsewhere. It remains to be seen whether this is the true physiological function of these proteins.
CHIF is an aldosterone-induced gene, expressed only in kidney collecting duct and distal colon surface cells (10, 11, 12). CHIF is up-regulated by stimuli that enhance Na+ absorption and K+ secretion, i.e. Na+ deprivation and K+ loading (12, 13, 14). CHIF knockout mice exhibit an abnormality in water absorption that is secondary to a defect in electrolyte transport (15).
too is a kidney-specific FXYD protein. However, the distribution of CHIF and
along the nephron is quite different and is, in fact, mutually exclusive (8, 12). Expression of two
splice variants (
a and
b) is moderate in proximal tubules and heavy in the medullary thick ascending limb; there is a difference in distribution of
a and
b in various distal cortical segments, with little or no expression of either
a or
b in the cortical connecting tubules and collecting duct and a low level of expression of
a in the inner medullary collecting duct (8, 16, 17, 18). CHIF on the other hand, is located only along the collecting duct and distal colon (8, 11, 12). Both CHIF and
are immunoprecipitated by antibodies raised against the
subunit of the Na,K-ATPase, and the co-immunoprecipitation is efficient only in conditions that preserve native pump structure (8, 19). The effects of
and CHIF on the pump kinetics are, however, quite different.
raises the apparent affinity for ATP by shifting the E1-E2 conformational equilibrium toward E1, and reduces apparent affinity for cytoplasmic Na+ ions by increasing the affinity of cytoplasmic K+ ions as competitors for cytoplasmic Na+ ions (5, 17). On the other hand, CHIF increases the affinity of the pump for cell Na+ and has no effect on the affinity for ATP (7, 8).
Although the functional effects of CHIF and
appear to be well established, it is not known which domains and which residues interact with the
and/or
subunits and affect the pump kinetics. The current study provides the first systematic analysis of structure-function relations of CHIF and
. It is demonstrated that the stability in detergent of the complexes formed with the
and
subunits is determined by the transmembrane segments, especially the residues Gly45, Met55, and Ala56. The trans-membrane segment also determines the opposite effects of CHIF and
on the Na+ affinity, but the amino acids involved in this functional effect are different from those responsible for stable interactions with
.
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EXPERIMENTAL PROCEDURES
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cDNAs, Antibodies, and Transfected Cell LinescDNAs that contain the coding sequences of rat CHIF,
a and
b, subcloned into the mammalian expression vector pIRES-hyg (Clontech), were described previously (8, 20). The various domains in CHIF were defined as follows: extracellular, Met1Gln38; transmembrane, Leu39Leu57; and intracellular, Ser58Thr87. These domains were replaced by the corresponding regions in rat
a or
b using standard recombinant DNA procedures and verified by sequencing. HeLa cells overexpressing the rat
1 subunit of Na,K-ATPase (HeLa-
1 cells, kindly provided by Dr. J. B. Lingrel, University of Cincinnati College of Medicine, Cincinnati, OH) were transfected using Polyfect (Qiagen) according to the manufacturer's instructions. Colonies expressing the FXYD constructs were selected in 400 µg/ml hygromycin B and tested by Western blotting. The following antibodies have been used: (a) a polyclonal antibody to the last 13 amino acids of rat CHIF (12); (b) a polyclonal antibody to the 10 C-terminal amino acids of
(20); (c) a polyclonal antibody to the N-terminal residues MDRWYL of
b (20); (d) a monoclonal antibody directed against the N-terminal segment of the
subunit (6H, kindly provided by Dr. M. J. Caplan, Yale University School of Medicine, New Haven, CT) (5); and (e) a polyclonal antibody, raised against the C-terminal tail sequence of the
subunit (KETYY, kindly provided by Dr. J. Kyte, University of California at San Diego, La Jolla, CA).
Immunoprecipitation, Western Blotting, and 86Rb+ Fluxes Transfected HeLa-
1 cells were solubilized in different concentrations of C12E10 in the presence of Rb+ and ouabain. The particular material was removed by centrifugation, and the soluble fraction was immunoprecipitated with the anti-
antibody (6H), as described in Ref. 8. Total soluble proteins and immunopellets were blotted for the presence of FXYD and
as described previously (21, 22) using the following antibodies: anti-KETTY (1:3000), anti-CHIF (1:500), and anti-
(C or N tail, 1:250). The blots were overlaid with horseradish peroxidase-coupled goat anti rabbit IgG (1:10,000) and analyzed by enhanced chemiluminescence. The abundance of FXYD message in stably transfected cell clones was determined by semi-quantitative PCR. RNA was extracted using TriReagent® (Molecular Research Center, Inc.), and cDNA was reverse transcribed from the poly(A)+ tail using SuperScript 2 RNase H (Invitrogen). It was amplified in LightCycler (Roche Applied Science) using specific primers corresponding to the FXYD and the pIRES-HYG sequences. The data were normalized by parallel amplification of GAPDH. 86Rb+ uptake was measured in monensin-permeabilized transfected HeLa-
1 cells as detailed in Refs. 8 and 23.
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RESULTS
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Previously, we demonstrated that CHIF,
, and phospholemman are specifically co-immunoprecipitated with the
subunit of Na,K-ATPase (6, 8). For both CHIF and
co-immunoprecipitation was efficient only in conditions known to preserve the native pump conformations, namely when solubilization of membranes was done with C12E10 in the presence of Rb+ plus ouabain or Na+ plus oligomycin. Fig. 1 depicts an experiment in which HeLa-
1 cells stably transfected with either CHIF or
b were solubilized with increasing concentrations of C12E10 plus Rb+ and ouabain and subjected to immunoprecipitation by an anti-
antibody. In both cases the FXYD protein co-immunoprecipitated with
. However, quantitative differences between CHIF and
were apparent. Although for
5% of the total protein was precipitated by this protocol, and the
/
complex was stable up to 1.5 mg/ml C12E10, less than 1.5% of the total amount of CHIF could be precipitated by the anti-
antibody, and the yield decreased sharply at increased detergent concentrations. Other experiments have demonstrated that the immunoprecipitation efficiency does not decrease with increasing concentration of the solubilized proteins, suggesting that the amount of antibody is not a limiting factor (data not shown). Based on the above findings one could assume that the efficiency of co-immunoprecipitation is determined by FXYD/
subunit interactions, which are also relevant in the intact membrane. FXYD proteins may interact with
as well as
subunit and be immunoprecipitated by the anti-
antibody because of the tight
/
association.
The difference in sensitivity to the detergent has been used to identify domains and residues responsible for the stability of the CHIF/
and
/
complexes in C12E10. Both CHIF and
have an extracellular N terminus (e), which in the case of CHIF includes also a signal peptide; a transmembrane segment (m); and an intracellular C terminus (i) (3, 7, 12). Chimeras in which one of these domains originates from one FXYD protein and the rest of the protein from the other were constructed and transfected in HeLa-
1 cells (Fig. 2A). For four of the six constructs, cell clones expressing the chimeric proteins at levels comparable with those of CHIF and
in native tissue could be selected (Fig. 2B). As reported previously (5),
b was expressed in transfected cells as a doublet (
b and
b'), of which
b' could be a post-translationally modified product. It is different from the doublet seen in kidney medulla, which reflects expression of
a and
b. A similar doublet (
b and
b') was apparent in cells expressing
be
mCi, whereas only a single band appeared in cells transfected with Ce
m
i of Ce
mCi. Thus,
b' may carry a post-translational modification in the external domain of
. Two chimeras that have the extracellular domain of
and the trans-membrane segment of CHIF,
eCmCi and
eCm
i, produced little or no protein. The same observation has been made irrespective of the
splice variant used (
a or
b). Despite the lack of expression of these proteins, the chimeric cDNAs did transcribe mRNA at levels 30200% of those of the nonchimeric constructs (not shown). Thus, the lack of expression of the protein may reflect inherent instability of these particular structures.
The four chimeras that were expressed were tested for co-immunoprecipitation with
and stability of the FXYD/
complex at increasing concentrations of C12E10 (Fig. 3). The key observation is that stability of the different chimera in C12E10 correlates with the origin of their transmembrane domain. Thus, the protein Ce
mCi behaved like
and could be effectively immunoprecipitated (>8%) at 1.5 mg/ml C12E10 (Fig. 3). On the other hand, exchanging the cytoplasmic domains or the N termini between the two FXYD proteins was without effect, i.e. Ce
m
i and
e
mCi behaved as
, whereas CeCm
i behaved as CHIF. Previous observations indicated that the phospholemman/
complex too is stable at relatively high concentrations of C10E12 (6). However, replacing the transmembrane domain of CHIF with that of phospholemman (P) did not substantially increase the immunoprecipitation efficiency at 2 mg/ml C12E10, i.e. the anti-
antibody immunoprecipitated 0.4 ± 0.2% (4) of the CHIF protein, 0.7 ± 0.4% (4) CePmCi, and 7.0 ± 3.6% (3) phospholemman. Thus, there must be factors in addition to the transmembrane segments that are significant for stabilizing the interaction (see "Discussion").
To further analyze the amino acids involved in the FXYD/
interactions, we have mutated different transmembrane residues and examined the consequences for stability of the CHIF/
complex. Initially, multiple mutations of transmembrane CHIF residues to the corresponding
positions were tested (Fig. 4). The data indicated that mutagenesis can indeed increase immunoprecipitation efficiency at 2 mg/ml C12E10 and abolish the decrease in complex stability upon raising detergent concentration from 0.35 to 2 mg/ml C12E10 (Fig. 4B). Further analysis demonstrated the existence of at least two different residues mediating this effect. One is in the range Gly45Ile53 and the other in the range Ala54Ala56 (Fig. 4C).
Next, various single and double mutations of transmembrane CHIF residues to the corresponding
residues were constructed and assayed for immunoprecipitation with
(Fig. 5). Three point mutations were found to independently increase complex stability in C12E10. These are G45A, M55I, and A56L. The double mutant M55I/A56L produced a complex that was significantly more stable than either M55I or A56L alone, suggesting that their effects are not mutually exclusive.
CHIF and
have opposite effects on the apparent affinity of the Na,K-ATPase for cell Na+. Co-expression of CHIF with
increases the affinity for intracellular Na+, whereas
decreases it (3, 5, 7, 8, 17, 24). Therefore, it was of interest to evaluate whether mutations that stabilize the CHIF/
complex also change the functional effects of this protein. Accordingly, effects on the pump kinetics of CHIF,
, and the two CHIF triple mutants were compared (Fig. 6 and Table I). As expected, CHIF decreased and
increased K0.5 for Na+ relative to the values measured in cell transfected with empty vector. The triple mutant A54L/M55I/A56L behaved essentially liked CHIF and increased the apparent affinity to Na+ even more than CHIF. Thus, these residues, which include two of the three amino acids that stabilize the CHIF/
complex, are not responsible for the different functional effects of CHIF and
. Similarly, another triple mutation of residues that varies between CHIF and
, Q38R/M42L/C49F, was without effect on function.

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FIG. 6. Effects of point mutations in CHIF on the Na+ affinity. 86Rb+ uptake was measured for different Na+ activities as described under "Experimental Procedures." The initial rates of the ouabain-sensitive fluxes were fitted to Michaelis-Menten kinetics. To average different experiments, the data were expressed as V/Vmax. The means ± S.E. of three to seven experiments are depicted.
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To further assess the functional role of different FXYD domains, we have tested the effects of the various chimeras on the affinity of the pump for cell Na+. These experiments, summarized in Fig. 7, clearly demonstrated that although the triple mutations described above were without effect, the differences in Na+ affinity conferred by CHIF or
are governed by the transmembrane domain of these proteins. Thus, chimeras in which the C or N terminus of
was replaced by the corresponding CHIF sequences (
e
mCi and Ce
m
i) behaved like
and increased K0.5. Similarly, a CHIF construct in which the C terminus was replaced by that of
(CeCm
i) behaved like CHIF. On the other hand, a CHIF construct with the trans-membrane domain derived from
(Ce
mCi) increased K0.5, like
. As described above, the opposite construct (
eCm
i) did not express protein. Protein was expressed, however, if the chimera had, in addition, the triple mutation AMA
LIL. This mutated construct (
eC*m
i) decreased K0.5 like CHIF, although the mutation alone (A54L/M55I/A56L) was without effect. Taken together, the above data indicate that the transmembrane interactions also control the effects of CHIF and
on the Na+ affinity of the pump, but the interactions involved differ from those shown to control the FXYD/
complex stability. It should be noted that a source of error in these experiments is a variable level of FXYD expression in the transfected cells. Thus, if the FXYD:
stoichiometry is less than 1, the observed change in K0.5 will be less than maximal. Accordingly, the only rigorous conclusion to be drawn from such experiments is whether a particular chimera increases or decreases Na+ affinity. The observed magnitude of the effect could be an underestimation of the true one.
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DISCUSSION
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FXYD is a newly discovered family of single-span transmembrane proteins with a common extracellular motif (1). Four members of this group have been shown to interact with the
subunit of the Na,K-ATPase and alter the pump kinetics (3, 5, 6, 7, 8, 9). The working hypothesis is that FXYD proteins are tissue-specific regulators of the pump. Their function would be to adjust the pump kinetics in a specific tissue, cell type, or physiological state, without affecting it elsewhere.
CHIF and
are two epithelial specific members of this family expressed primarily along the kidney nephron or in distal colon (CHIF) (8, 11, 12, 16, 17). The two proteins have opposite effects on the affinity of the pump for cytoplasmic Na+ (5, 8, 17) and interact differently with
(25). These differences have been used to study their structure-function relationships using chimeras formed between the two proteins, as well as point mutations. The major observation was that both the effect on the Na+ affinity and the stability of the complex in detergent are determined by the transmembrane segment, which is the most conserved region of the seven members of the FXYD protein family. Obviously, this does not exclude important structural and functional roles of the N and C termini. It has been reported that the FXYD sequence in the extracellular domain is itself essential for assembly of CHIF and
with the pump (7). In addition, the anti-C-terminal antibody abrogates the effect of
on ATP affinity but not that on sodium affinity, suggesting the existence of more than one interaction (5). It has been shown recently that both the C-terminal cytoplasmic and N-terminal extracellular sequences of the
subunit affect the ATP affinity (26).
One indication for stability of the FXYD/
/
complex in detergent is the efficiency of co-immunoprecipitation (Fig. 1). Because the soluble complexes preserve both the structural and functional integrity of the native complexes (27), we assume that this parameter is also indicative of protein/protein interactions that are relevant in the intact membrane. We found that the normal low stability of the CHIF/
/
complex can be increased by 410-fold to values characteristic of
/
/
or phospholemman/
/
oligomers, by mutating one of three residues to the corresponding amino acids in
, i.e. G45A, M55I, or A56L. Helical wheel projection indicates that Gly45 and Ala56 face the same direction, whereas Met55 is oriented at an angle of
100° (Fig. 5, inset). Thus, the above stabilizing mutations appear to be involved in interactions with two other helices in
and/or
. Interestingly, these residues appear to be well conserved among FXYD proteins species. All of the available CHIF sequences (mouse, rat, and human) have Gly at position 45, but all other FXYD have a well conserved Ala at this position (1). Similarly, other FXYD proteins have Ile, Leu, or Val in the positions corresponding to CHIF Met55 and Ala56.
The transmembrane domain also appears to govern at least one of the functional effects of CHIF and
. Exchanging these segments reversed the direction of the change in Na+ affinity, whereas substituting the N- or C-terminal sequences that lie outside the membrane was without effect on this parameter. Thus, intra-membrane interactions also determine at least one of the kinetic effects of these FXYD proteins. However, this functional interaction is different from that determining the stability of the complex because it is not affected by mutating 54AMA into LIL. Three other mutations of nonconserved transmembrane residues (Q38R/M42L/C49F) were also ineffective in altering Na+ affinity. The effect on Na+ affinity must therefore be mediated by other residues or depends on a more complex interaction that requires a specific combination of the above residues. For example it is just conceivable that the 54AMA to LIL mutation decrease KATP and secondarily KNa, thereby mask a
-like effect on the K+/Na+ antagonism. To detect this kind of complex interaction, expression systems permitting more detailed functional analysis will be required. In conclusion, the present study provides the first systematic analysis of structure-function relations of FXYD proteins and highlights the important functional and structural role of the trans-membrane segment.
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FOOTNOTES
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* This work was supported by research grants from the Minerva Foundation and the Israeli Science Foundation (to H. G. and S. J. D. K.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. 
William Smithburg Chair of Biochemistry. 
Hella and Derrick Kleeman Chair of Biochemistry. To whom correspondence should be addressed. Tel.: 972-8-9342706; Fax: 972-8-9344177; E-mail: h.garty{at}weizmann.ac.il.
1 The abbreviation used is: CHIF, corticosteroid hormone-induced factor. 
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REFERENCES
|
---|
- Sweadner, K. J., and Rael, E. (2000) Genomics 68, 4156[CrossRef][Medline]
[Order article via Infotrieve]
- Mercer, R. W., Biemesderfer, D., Bliss, D. P., Collins, J. H., and Forbush, B. (1993) J. Cell Biol. 121, 579586[Abstract]
- Beguin, P., Wang, X. Y., Firsov, D., Puoti, A., Claeys, D., Horisberger, J. D., and Geering, K. (1997) EMBO J. 16, 42504260[Abstract/Free Full Text]
- Therien, A. G., Goldshleger, R., Karlish, S. J. D., and Blostein, R. (1997) J. Biol. Chem. 272, 3262832634[Abstract/Free Full Text]
- Therien, A. G., Karlish, S. J., and Blostein, R. (1999) J. Biol. Chem. 274, 1225212256[Abstract/Free Full Text]
- Crambert, G., Fuzesi, M., Garty, H., Karlish, S., and Geering, K. (2002) Proc. Natl. Acad. Sci. U. S. A. 99, 1147611481[Abstract/Free Full Text]
- Béguin, P., Crambert, G., Guennoun, S., Garty, H., Horisberger, J.-D., and Geering, K. (2001) EMBO J. 20, 39934002[Abstract/Free Full Text]
- Garty, H., Lindzen, M., Scanfano, R., Aizman, R., Fuzesi, M., Goldshleger, R., Farman, N., Blostein, R., and Karlish, S. J. D. (2002) Am. J. Physiol. 283, F607F615
- Beguin, P., Crambert, G., Monnet-Tschudi, F., Uldry, M., Horisberger, J. D., Garty, H., and Geering, K. (2002) EMBO J. 21, 32643273[Abstract/Free Full Text]
- Attali, B., Latter, H., Rachamim, N., and Garty, H. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 60926096[Abstract/Free Full Text]
- Capurro, C., Bonvalet, J. P., Escoubet, B., Garty, H., and Farman, N. (1996) Am. J. Physiol. 271, C753C762[Medline]
[Order article via Infotrieve]
- Shi, H.-K., Levy-Holzman, R., Cluzeaud, F., Farman, N., and Garty, H. (2001) Am. J. Physiol. 280, F505F515
- Wald, H., Goldstein, O., Asher, C., Yagil, Y., and Garty, H. (1996) Am. J. Physiol. 271, F322F329[Medline]
[Order article via Infotrieve]
- Wald, H., Popovtzer, M. M., and Garty, H. (1997) Am. J. Physiol. 272, F617F623[Medline]
[Order article via Infotrieve]
- Aizman, R., Asher, C., Fuzesi, M., Latter, H., Lonai, P., Karlish, S. J., and Garty, H. (2002) Am. J. Physiol. 283, F569F577
- Wetzel, R. K., and Sweadner, K. J. (2001) Am. J. Physiol. 281, F531F545
- Pu, H. X., Cluzeaud, F., Goldshleger, R., Karlish, S. J. D., Farman, N., and Blostein, R. (2001) J. Biol. Chem. 276, 2037020378[Abstract/Free Full Text]
- Pihakaskie-Maunsbach, K., Vorum, H., Else-Merete, L., Garty, H., Karlish, S. J. D., and Maunsbach, A. B. (2003) Ann. N. Y. Acad. Sci., in press
- Garty, H., Lindzen, M., Füzesi, M., Aizman, R., Goldshleger, R., Asher, C., and Karlish, S. J. D. (2003) Ann. N. Y. Acad. Sci., in press
- Kuster, B., Shainskaya, A., Pu, H. X., Goldshleger, R., Blostein, R., Mann, M., and Karlish, S. J. (2000) J. Biol. Chem. 275, 1844118446[Abstract/Free Full Text]
- Capasso, J. M., Hoving, S., Tal, D. M., Goldshleger, R., and Karlish, S. J. (1992) J. Biol. Chem. 267, 11501158[Abstract/Free Full Text]
- Goldshleger, R., Tal, D. M., and Karlish, S. J. (1995) Biochemistry 34, 86688679[Medline]
[Order article via Infotrieve]
- Munzer, J. S., Daly, S. E., Jewell-Motz, E. A., Lingrel, J. B., and Blostein, R. (1994) J. Biol. Chem. 269, 1666816676[Abstract/Free Full Text]
- Arystarkhova, E., Wetzel, R. K., Asinovski, N. K., and Sweadner, K. J. (1999) J. Biol. Chem. 274, 3318333185[Abstract/Free Full Text]
- Lindzen, M., Aizman, R., Lifshitz, Y., Karlish, S. J. D., and Garty, H. (2003) Ann. N. Y. Acad. Sci., in press
- Pu, H. X., Scanzano, R., and Blostein, R. (2002) J. Biol. Chem. 277, 2027020276[Abstract/Free Full Text]
- Carradus, M., Shainskaya, A., Barber, J., and Karlish, S. J. D. (2000) Excerpta Medica ICS 1207, 301304