Mutational analysis of histidine residues in the human proton-coupled amino acid transporter PAT1

The proton-coupled amino acid transporter 1 (PAT1) represents a major route by which small neutral amino acids are absorbed after intestinal protein digestion. The system also serves as a novel route for oral drug delivery. Having shown that H⁺ affects affinity constants but not maximal velocity of transport, we investigated which histidine residues are obligatory for PAT1 function. Three histidine residues are conserved among the H⁺-coupled amino acid transporters PAT1 to 4 from different animal species. We individually mutated each of these histidine residues and compared the catalytic function of the mutants with that of the wild type transporter after expression in HRPE cells. His-55 was found to be essential for the catalytic activity of hPAT1 because the corresponding mutants H55A, H55N and H55E had no detectable l-proline transport activity. His-93 and His-135 are less important for transport function since H93N and H135N mutations did not impair transport function. The loss of transport function of His-55 mutants was not due to alterations in protein expression as shown both by cell surface biotinylation immunoblot analyses and by confocal microscopy. We conclude that His-55 might be responsible for binding and translocation of H⁺ in the course of cellular amino acid uptake by PAT1.     

Substrate specificity of the amino acid transporter PAT1

Summary. The proton coupled amino acid transporter PAT1 expressed in intestine, brain, and other organs accepts L- and D-proline, glycine, and L-alanine but also pharmaceutically active amino acid derivatives such as 3-amino-1-propanesulfonic acid, L-azetidine-2-carboxylic acid, and cis-4-hydroxy-D-proline as substrates. We systematically analyzed the structural requirements for PAT1 substrates by testing 87 amino acids, proline homologs, indoles, and derivatives. Affinity data and effects on membrane potential were determined using Caco-2 cells. For aliphatic amino acids, a blocked carboxyl group, the distance between amino and carboxyl group, and the position of the hydroxyl group are affinity limiting factors. Methylation of the amino group enhances substrate affinity. Hetero atoms in the proline template are well tolerated. Aromatic α-amino acids display low affinity. PAT1 interacts strongly with heterocyclic aromatic acids containing an indole scaffold. The structural requirements of PAT1 substrates elucidated in this study will be useful for the development of prodrugs.     

Transport of l-proline by the proton-coupled amino acid transporter PAT2 in differentiated 3T3-L1 cells

Mechanism and substrate specificity of the proton-coupled amino acid transporter 2 (PAT2, SLC36A2) have been studied so far only in heterologous expression systems such as HeLa cells and Xenopus laevis oocytes. In this study, we describe the identification of the first cell line that expresses PAT2. We cultured 3T3-L1 cells for up to 2 weeks and differentiated the cells into adipocytes in supplemented media containing 2 μM rosiglitazone. During the 14 day differentiation period the uptake of the prototype PAT2 substrate l-[³H]proline increased ~5-fold. The macro- and microscopically apparent differentiation of 3T3-L1 cells coincided with their H⁺ gradient-stimulated uptake of l-[³H]proline. Uptake was rapid, independent of a Na⁺ gradient but stimulated by an inwardly directed H⁺ gradient with maximal uptake occurring at pH 6.0. l-Proline uptake was found to be mediated by a transport system with a Michaelis constant (K_t) of 130 ± 10 μM and a maximal transport velocity of 4.9 ± 0.2 nmol × 5 min^?1 mg of protein^?1. Glycine, l-alanine, and l-tryptophan strongly inhibited l-proline uptake indicating that these amino acids also interact with the transport system. It is concluded that 3T3-L1 adipocytes express the H⁺-amino acid cotransport system PAT2.     

Substrate recognition by the mammalian proton-dependent amino acid transporter PAT1

The PAT family of proton-dependent amino acid transporters has recently been identified at the molecular level. This paper describes the structural requirements in substrates for their interaction with the cloned murine intestinal proton/amino acid cotransporter (PAT1). By using the Xenopus laevis oocytes as an expression system and by combining the two-electron voltage clamp technique with radiotracer flux studies, it was demonstrated that the aliphatic side chain of L-alpha-amino acids substrates can consist maximally of only one CH2-unit for high affinity interaction with PAT1. With respect to the maximal separation between the amino and carboxyl groups, only two CH2-units, as in gamma-aminobutyric acid (GABA), are tolerated. PAT1 displays no or even a reversed stereoselectivity, tolerating serine and cystein only in the form of D-enantiomers. A methyl-substitution of the carboxyl group (e.g. O-methyl-glycine) markedly diminishes substrate affinity and transport rates, whereas methyl-substitutions at the amino group (e.g. sarcosine or betaine) have only minor effects on substrate interaction with the transporter binding site. Furthermore, it has been shown (by kinetic analyses of radiolabelled betaine influx and inhibition studies) that the endogenous PAT system of human Caco-2 cells has very similar transport characteristics to mouse PAT1. In summary, one has defined the structural requirements and limitations thet determine the substrate specificity of PAT1. A critical recognition criterion of PAT1 is the backbone charge separation distance and the side chain size, whereas substitutions on the amino group are well tolerated.     

Substrate recognition by the mammalian proton-dependent amino acid transporter PAT1

The PAT family of proton-dependent amino acid transporters has recently been identified at the molecular level. This paper describes the structural requirements in substrates for their interaction with the cloned murine intestinal proton/amino acid cotransporter (PAT1). By using Xenopus laevis oocytes as an expression system and by combining the two-electrode voltage clamp technique with radiotracer flux studies, it was demonstrated that the aliphatic side chain of L-α-amino acids substrates can consist maximally of only one CH₂-unit for high affinity interaction with PAT1. With respect to the maximal separation between the amino and carboxyl groups, only two CH₂-units, as in γ-aminobutyric acid (GABA), are tolerated. PAT1 displays no or even a reversed stereoselectivity, tolerating serine and cysteine only in the form of the D-enantiomers. A methyl-substitution of the carboxyl group (e.g. O-methyl-glycine) markedly diminishes substrate affinity and transport rates, whereas methyl-substitutions at the amino group (e.g. sarcosine or betaine) have only minor effects on substrate interaction with the transporter binding site. Furthermore, it has been shown (by kinetic analysis of radiolabelled betaine influx and inhibition studies) that the endogenous PAT system of human Caco-2 cells has very similar transport characteristics to mouse PAT1. In summary, one has defined the structural requirements and limitations that determine the substrate specificity of PAT1. A critical recognition criterion of PAT1 is the backbone charge separation distance and side chain size, whereas substitutions on the amino group are well tolerated.     

Critical amino acid residues in transmembrane domain 1 of the human organic anion transporter hOAT1

Human organic anion transporter 1 (hOAT1) belongs to a superfamily of organic anion transporters, which play critical roles in the body disposition of clinically important drugs, including anti-human immunodeficiency virus therapeutics, anti-tumor drugs, antibiotics, anti-hypertensives, and anti-inflammatories. Previously we suggested that the predicted transmembrane domain 1 (TM1) of hOAT1 might be important for its function. In the present study, we examined the role of each residue within TM1 of hOAT1 in substrate recognition and transport. Alanine scanning was used to construct mutants of hOAT1, and the uptake of model substrate para-aminohippurate was studied in COS-7 cells expressing the mutant transporters. This approach led to the discovery of two critical amino acid residues, Leu-30 and Thr-36. A substitution of Leu-30 or Thr-36 with alanine resulted in a complete loss of transport activities. We then further characterized Leu-30 and Thr-36 by mutagenizing these residues to amino acids with different physicochemical properties. Leu-30 was replaced with amino acids with varying sizes of side chains, including glycine, valine, and isoleucine. We showed that progressively smaller side chains at position 30 increasingly impaired hOAT1 function mainly because of the impaired surface expression of the transporter. Thr-36, another critical amino acid in TM1, was replaced by serine and cysteine. Similar to the substitution of Thr-36 by alanine, substitution by serine and cysteine at this position abolished transport activity without affecting the surface expression of the transporter. The fact that Thr-36 cannot be substituted with serine and that the side chains of alanine, serine, and cysteine are smaller than that of threonine by a methyl group indicate that both the methyl group and the hydroxyl group of Thr-36 could be critical for hOAT1 activity. Together we conclude that Leu-30 and Thr-36 play distinct roles in hOAT1 function. Leu-30 is important in targeting the transporter to the plasma membrane. In contrast, Thr-36 is critical for substrate recognition. The present study provided the first molecular evidence that transmembrane domain 1 is a critical determinant of hOAT1 function and may provide important insights into the structure-function relationships of the organic anion transporter family.     

The amino acid transporter PAT1 regulates mTORC1 in a nutrient-sensitive manner that requires its transport activity

The proton-coupled amino acid transporter PAT1 has been postulated to regulate the amino acid-stimulated mTORC1 through two different mechanisms, either it activates mTORC1 by sensing and transducing the lysosomal amino acid signal to mTORC1, or it inhibits mTORC1 by decreasing the signal level, as increased PAT1 has been shown to either activate or inactivate mTORC1 in the human embryonic kidney HEK293 cells. The current study aims to clarify the cause of these controversial observations, which is promoted by the recent discovery that the lysosomal PAT1 can be induced by starvation. Here, we show that under the normal culture condition, overexpression of PAT1 did not apparently change the mTORC1 activity in the fast proliferating cells. However when these cells were synchronized by starvation, followed by nutrient replenishment for a short period of time, the mTORC1 activity was decreased by PAT1 overexpression; if the nutrient stimulation lasted for longer time, the mTORC1 activities could be recovered in the PAT1-overexpressing cells. In addition, we showed the starvation-induced lysosomal PAT1 was gradually decreased during the nutrient replenishment. These results reveal that the influence of PAT1 on mTORC1 seems to be affected by the nutrient condition and the level of lysosomal PAT1. We further demonstrate that suppressing the transport activity of PAT1 abolished its inhibitory effect on mTORC1. Our data support a mechanism that PAT1 can negatively regulate mTORC1 by controlling the cellular nutrient signal level.     

Mutational properties of amino acid residues: implications for evolvability of phosphorylatable residues

As Fran?ois Jacob pointed out over 30 years ago, evolution is a tinkering process, and, as such, relies on the genetic diversity produced by mutation subsequently shaped by Darwinian selection. However, there is one implicit assumption that is made when studying this tinkering process; it is typically assumed that all amino acid residues are equally likely to mutate or to result from a mutation. Here, by reconstructing ancestral sequences and computing mutational probabilities for all the amino acid residues, we refute this assumption and show extensive inequalities between different residues in terms of their mutational activity. Moreover, we highlight the importance of the genetic code and physico-chemical properties of the amino acid residues as likely causes of these inequalities and uncover serine as a mutational hot spot. Finally, we explore the consequences that these different mutational properties have on phosphorylation site evolution, showing that a higher degree of evolvability exists for phosphorylated threonine and, to a lesser extent, serine in comparison with tyrosine residues. As exemplified by the suppression of serine's mutational activity in phosphorylation sites, our results suggest that the cell can fine-tune the mutational activities of amino acid residues when they reside in functional protein regions.     

Mutational analysis of the human immunodeficiency virus type 1 Rev transactivator: essential residues near the amino terminus.

The expression of certain mRNAs from human immunodeficiency virus type 1 (HIV-1) is controlled by the viral transactivator Rev, a nucleolar protein that binds a cis-acting element in these mRNAs. Rev is encoded by two viral exons that specify amino acids 1 to 26 and 27 to 116, respectively. Earlier studies have mapped essential regions of the protein that are encoded in the second exon. By further mutational analysis of Rev, we have now identified a novel locus encoded by the first exon that also is essential for transactivation in vivo. Defined by mutations at residues 14 to 20, this locus coincides with a cluster of positively charged and nonpolar amino acids that is conserved in Rev proteins of all known primate immunodeficiency viruses. Rev proteins that contained mutations at this site were defective in both nuclear localization and transactivation and did not function as trans-dominant inhibitors of wild-type Rev. Fusion of these mutants to a heterologous nuclear protein complemented the defect in localization but did not restore biological activity. Our findings suggest that this N-terminal locus may play a direct role in transactivation, perhaps contributing to essential protein-protein interactions or forming part of the RNA-binding domain of Rev.     

Functional role of specific amino acid residues in human thiamine transporter SLC19A2: mutational analysis

SLC19A2 is a membrane thiamine transporter expressed in a variety of human tissues, including the gastrointestinal tract. Little is currently known about the structure/function relationship of SLC19A2. We examined the effect of introducing mutations in SLC19A2 identical to those found in thiamine-responsive megaloblastic anemia syndrome (TRMA), on functional activity and membrane expression of the transporter. We also examined the effect of mutating the only conserved anionic residue (E138) in the transmembrane (TM) domains of the SLC19A2 and that of the putative glycosylation sites (N63, N314). Northern blot analysis showed SLC19A2 mRNA was expressed at the same level in HeLa cells transfected with wild-type or mutated SLC19A2. Introducing the clinically relevant mutations (D93H, S143F, G172D) or mutation at the conserved anionic residue (E138A) of SLC19A2 led to a significant (P < 0.01) inhibition of thiamine uptake. Mutations of the two potential N-linked glycosylation sites (N63Q, N314Q) of SLC19A2 did not affect functional activity; they did, however, lead to a noticeable reduction in apparent molecular weight of protein. Western blot analysis showed all proteins (except D93H) were expressed in the membrane (not the cytoplasmic) fraction of HeLa cells. These results provide direct confirmation that clinically relevant mutations in SLC19A2 observed in TRMA cause malfunctioning of the transporter and/or a defect in its translation/stability. Results also show conserved TM anionic residue of the SLC19A2 protein is critical for its function. Furthermore, native SLC19A2 is glycosylated, but this is not important for its function.     

Site-directed mutagenesis of cysteine residues of large neutral amino acid transporter LAT1

The large neutral amino acid transporter type 1, LAT1, is the principal neutral amino acid transporter expressed at the blood-brain barrier (BBB). Owing to the high affinity (low K_m) of the LAT1 isoform, BBB amino acid transport in vivo is very sensitive to transport competition effects induced by hyperaminoacidemias, such as phenylketonuria. The low K_m of LAT1 is a function of specific amino acid residues, and the transporter is comprised of 12 phylogenetically conserved cysteine (Cys) residues. LAT1 is highly sensitive to inhibition by inorganic mercury, but the specific cysteine residue(s) of LAT1 that account for the mercury sensitivity is not known. LAT1 forms a heterodimer with the 4F2hc heavy chain, which are joined by a disulfide bond between Cys¹⁶⁰ of LAT1 and Cys¹¹⁰ of 4F2hc. The present studies use site-directed mutagenesis to convert each of the 12 cysteines of LAT1 and each of the 2 cysteines of 4F2hc into serine residues. Mutation of the cysteine residues of the 4F2hc heavy chain of the hetero-dimeric transporter did not affect transporter activity. The wild type LAT1 was inhibited by HgCl₂ with a K_i of 0.56 ± 0.11 μM. The inhibitory effect of HgCl₂ for all 12 LAT1 Cys mutants was examined. However, except for the C439S mutant, the inhibition by HgCl₂ for 11 of the 12 Cys mutants was comparable to the wild type transporter. Mutation of only 2 of the 12 cysteine residues of the LAT1 light chain, Cys⁸⁸ and Cys⁴³⁹, altered amino acid transport. The V_max was decreased 50% for the C88S mutant. A kinetic analysis of the C439S mutant could not be performed because transporter activity was not significantly above background. Confocal microscopy showed the C439S LAT1 mutant was not effectively transferred to the oocyte plasma membrane. These studies show that the Cys⁴³⁹ residue of LAT1 plays a significant role in either folding or insertion of the transporter protein in the plasma membrane.     

Site-directed mutagenesis of cysteine residues of large neutral amino acid transporter LAT1

The large neutral amino acid transporter type 1, LAT1, is the principal neutral amino acid transporter expressed at the blood-brain barrier (BBB). Owing to the high affinity (low Km) of the LAT1 isoform, BBB amino acid transport in vivo is very sensitive to transport competition effects induced by hyperaminoacidemias, such as phenylketonuria. The low Km of LAT1 is a function of specific amino acid residues, and the transporter is comprised of 12 phylogenetically conserved cysteine (Cys) residues. LAT1 is highly sensitive to inhibition by inorganic mercury, but the specific cysteine residue(s) of LAT1 that account for the mercury sensitivity is not known. LAT1 forms a heterodimer with the 4F2hc heavy chain, which are joined by a disulfide bond between Cys160 of LAT1 and Cys110 of 4F2hc. The present studies use site-directed mutagenesis to convert each of the 12 cysteines of LAT1 and each of the 2 cysteines of 4F2hc into serine residues. Mutation of the cysteine residues of the 4F2hc heavy chain of the hetero-dimeric transporter did not affect transporter activity. The wild type LAT1 was inhibited by HgCl2 with a Ki of 0.56+/-0.11 microM. The inhibitory effect of HgCl2 for all 12 LAT1 Cys mutants was examined. However, except for the C439S mutant, the inhibition by HgCl2 for 11 of the 12 Cys mutants was comparable to the wild type transporter. Mutation of only 2 of the 12 cysteine residues of the LAT1 light chain, Cys88 and Cys439, altered amino acid transport. The Vmax was decreased 50% for the C88S mutant. A kinetic analysis of the C439S mutant could not be performed because transporter activity was not significantly above background. Confocal microscopy showed the C439S LAT1 mutant was not effectively transferred to the oocyte plasma membrane. These studies show that the Cys439 residue of LAT1 plays a significant role in either folding or insertion of the transporter protein in the plasma membrane.     

Mutational analysis of amino acid residues involved in argininosuccinate lyase activity in duck delta II crystallin

Delta-crystallins are the major structural eye lens proteins of most birds and reptiles and are direct homologues of the urea cycle enzyme argininosuccinate lyase. There are two isoforms of delta-crystallin, delta Iota and delta IotaIota, but only delta IotaIota crystallin exhibits argininosuccinate lyase (ASL) activity. At the onset of this study, the structure of argininosuccinate lyase/delta IotaIota crystallin with bound inhibitor or substrate analogue was not available. Biochemical and X-ray crystallographic studies had suggested that H162 may function as the catalytic base in the argininosuccinate lyase/delta IotaIota crystallin reaction mechanism, either directly or indirectly through the activation of a water molecule. The identity of the catalytic acid was unknown. In this study, the argininosuccinate substrate was modeled into the active site of duck delta IotaIota crystallin, using the coordinates of an inhibitor-bound Escherichia coli fumarase C structure to orient the fumarate moiety of the substrate. The model served as a means of identifying active site residues which are positioned to potentially participate in substrate binding and/or catalysis. On the basis of the results of the modeling, site-directed mutagenesis was performed on several amino acids, and the kinetic and thermodynamic properties of each mutant were determined. Kinetic studies reveal that five residues, R115, N116, T161, S283, and E296, are essential for catalytic activity. Determination of the free energy of unfolding/refolding of wild-type and mutant delta II crystallins revealed that all constructs exhibit similar thermodynamic stabilities. During the course of this work, the structure of an inactive delta IotaIota crystallin mutant with bound substrate was solved [Vallee et al. (1999) Biochemistry 38, 2425-2434], which has allowed the kinetic data to be interpreted on a structural basis.     

Interactions between charged amino acid residues within transmembrane helices in the sulfate transporter SHST1

The aim of this study was to identify charged amino acid residues important for activity of the sulfate transporter SHST1. We mutated 10 charged amino acids in or near proposed transmembrane helices and expressed the resulting mutants in a sulfate transport-deficient yeast strain. Mutations affecting four residues resulted in a complete loss of sulfate transport; these residues were D107 and D122 in helix 1 and R354 and E366 in helix 8. All other mutants showed some reduction in transport activity. The E366Q mutant was unusual in that expression of the mutant protein was toxic to yeast cells. The R354Q mutant showed reduced trafficking to the plasma membrane, indicating that the protein was misfolded. However, transporter function (to a low level) and wild-type trafficking could be recovered by combining the R354Q mutation with either the E175Q or E270Q mutations. This suggested that R354 interacts with both E175 and E270. The triple mutant E175Q/E270Q/R354Q retained only marginal sulfate transport activity but was trafficked at wild-type levels, suggesting that a charge network between these three residues may be involved in the transport pathway, rather than in folding. D107 was also found to be essential for the ion transport pathway and may form a charge pair with R154, both of which are highly conserved. The information obtained on interactions between charged residues provides the first evidence for the possible spatial arrangement of transmembrane helices within any member of this transporter family. This information is used to develop a model for SHST1 tertiary structure.     

Functional investigation of conserved membrane-embedded glutamate residues in the proton-coupled peptide transporter YjdL

Proton-dependent oligopeptide transporters (POTs) are secondary active symporters that utilize the proton gradient to drive the inward translocation of di- and tripeptides. We have mutated two highly conserved membraneembedded glutamate residues (Glu20 and Glu388) in the E. coli POT YjdL to probe their possible functional roles, in particular if they were involved/implicated in recognition of the substrate N-terminus. The mutants (Glu20Asp, Glu20Gln, Glu388Asp, and Glu388Gln) were tested for substrate uptake, which indicated that both the negative charge and the side chain length were important for function. The IC50 values of dipeptides with lack of or varying N-terminus (Ac-Lys, Gly- Lys, β-Ala-Lys, and 4-GABA-Lys), showed that Gly-Lys and β-Ala-Lys ranged between ~0.1 to ~1.0 mM for wild type and Glu20 mutants. However, for Glu388Gln the IC50 increased to ~2.0 and > 10 mM for Gly-Lys and β-Ala-Lys, respectively, suggesting that Glu388, and not Glu20, is able to sense the position of the N-terminus and important for the interaction. Furthermore, uptake as a function of pH showed that the optimum at around pH 6.5 for wild type YjdL shifted to 7.0-7.5 for the Glu388Asp/Gln mutants while the Glu20Asp retained the wild type optimum. Uptake by the Glu20Gln on the other hand was completely unaffected by the bulk pH in the range tested, which indicated a possible role of Glu20 in proton translocation.     

Mutational analysis and modeling reveal functionally critical residues in transmembrane segments 1 and 3 of the UapA transporter

Earlier, we identified mutations in the first transmembrane segment (TMS1) of UapA, a uric acid-xanthine transporter in Aspergillus nidulans, that affect its turnover and subcellular localization. Here, we use one of these mutations (H86D) and a novel mutation (I74D) as well as genetic suppressors of them, to show that TMS1 is a key domain for proper folding, trafficking and turnover. Kinetic analysis of mutants further revealed that partial misfolding and deficient trafficking of UapA does not affect its affinity for xanthine transport, but reduces that of uric acid and confers a degree of promiscuity towards the binding of other purines. This result strengthens the idea that subtle interactions among domains not directly involved in substrate binding refine the selectivity of UapA. Characterization of second-site suppressors of H86D revealed a genetic interaction of TMS1 with TMS3, the latter segment shown for the first time to be important for UapA function. Systematic mutational analysis of polar and conserved residues in TMS3 showed that Ser154 is crucial for UapA transport activity. Our results are in agreement with a topological model of UapA built on the recently published structure of UraA, a bacterial homolog of UapA.     

Structure,tissue expression pattern,and function of the amino acid transporter rat PAT2

The second member of the PAT (proton-coupled amino acid transporter) family of H(+)-coupled, pH-dependent, Na(+)-independent amino acid transporters was isolated from a rat lung cDNA library. The cDNA for rat PAT2 is 2396bp in length, including 70bp of 5'UTR and a poly(A) tail. The transporter gene, consisting of 10 exons, is located on rat chromosome 10q22. The cDNA codes for a protein of 481 amino acids with 72% identity (over 449 amino acids) with rat PAT1. Tissue expression studies demonstrate that mRNA abundance is generally low with highest levels being detected in lung and spleen, with lower levels in the brain, heart, kidney, and skeletal muscle. Functional expression in either mammalian cells or Xenopus laevis oocytes demonstrates that rat PAT2 mediates pH-dependent, Na(+)-independent uptake of glycine, proline, and alpha(methyl)aminoisobutyric acid (MeAIB). In conclusion PAT2 has a limited tissue distribution, higher affinity (Michaelis-Menten constant for glycine uptake between 0.49 and 0.69mM), and distinct substrate specificity compared to PAT1.     

Mutational analysis of the ras converting enzyme reveals a requirement for glutamate and histidine residues

The Ras converting enzyme (RCE) promotes a proteolytic activity that is required for the maturation of Ras, the yeast a-factor mating pheromone, and certain other proteins whose precursors bear a C-terminal CAAX tetrapeptide motif. Despite the physiological importance of RCE, the enzymatic mechanism of this protease remains undefined. In this study, we have evaluated the substrate specificity of RCE orthologs from yeast (Rce1p), worm, plant, and human and have determined the importance of conserved residues toward enzymatic activity. Our findings indicate that RCE orthologs have conserved substrate specificity, cleaving CVIA, CTLM, and certain other CAAX motifs, but not the CASQ motif, when these motifs are placed in the context of the yeast a-factor precursor. Our mutational studies of residues conserved between the orthologs indicate that an alanine substitution at His194 completely inactivates yeast Rce1p enzymatic activity, whereas a substitution at Glu156 or His248 results in marginal activity. We have also determined that residues Glu157, Tyr160, Phe190, and Asn252 impact the substrate selectivity of Rce1p. Computational methods predict that residues influencing Rce1p function are all near or within hydrophobic segments. Combined, our data indicate that yeast Rce1p function requires residues that are invariably conserved among an extended family of prokaryotic and eukaryotic enzymes and that these residues are likely to lie within or immediately adjacent to the transmembrane segments of this membrane-localized enzyme.     

Functional roles of conserved amino acid residues surrounding the phosphorylatable histidine of the yeast phosphorelay protein YPD1

The histidine-containing phosphotransfer (HPt) protein YPD1 is an osmoregulatory protein in yeast that facilitates phosphoryl transfer between the two response regulator domains associated with SLN1 and SSK1. Based on the crystal structure of YPD1 and the sequence alignment of YPD1 with other HPt domains, we site-specifically engineered and purified several YPD1 mutants in order to examine the role of conserved residues surrounding the phosphorylatable histidine (H64). Substitution of the positively charged residues K67 and R90 destabilized the phospho-imidazole linkage, whereas substitution of G68 apparently reduces accessibility of H64. These findings, together with the effect of other mutations, provide biochemical support of the proposed functional roles of conserved amino acid residues of HPt domains.