Effect of Vitamin K-dependent Protein Precursor Propeptide,Vitamin K Hydroquinone,and Glutamate Substrate Binding on the Structure and Function of γ-Glutamyl Carboxylase

The γ-glutamyl carboxylase utilizes four substrates to catalyze carboxylation of certain glutamic acid residues in vitamin K-dependent proteins. How the enzyme brings the substrates together to promote catalysis is an important question in understanding the structure and function of this enzyme. The propeptide is the primary binding site of the vitamin K-dependent proteins to carboxylase. It is also an effector of carboxylase activity. We tested the hypothesis that binding of substrates causes changes to the carboxylase and in turn to the substrate-enzyme interactions. In addition we investigated how the sequences of the propeptides affected the substrate-enzyme interaction. To study these questions we employed fluorescently labeled propeptides to measure affinity for the carboxylase. We also measured the ability of several propeptides to increase carboxylase catalytic activity. Finally we determined the effect of substrates: vitamin K hydroquinone, the pentapeptide FLEEL, and NaHCO₃, on the stability of the propeptide-carboxylase complexes. We found a wide variation in the propeptide affinities for carboxylase. In contrast, the propeptides tested had similar effects on carboxylase catalytic activity. FLEEL and vitamin K hydroquinone both stabilized the propeptide-carboxylase complex. The two together had a greater effect than either alone. We conclude that the effect of propeptide and substrates on carboxylase controls the order of substrate binding in such a way as to ensure efficient, specific carboxylation.     

Binding of the factor IX gamma-carboxyglutamic acid domain to the vitamin K-dependent gamma-glutamyl carboxylase active site induces an allosteric effect that may ensure processive carboxylation and regulate the release of carboxylated product

Propeptides of the vitamin K-dependent proteins bind to an exosite on gamma-glutamyl carboxylase; while they are bound, multiple glutamic acids in the gamma-carboxyglutamic acid (Gla) domain are carboxylated. The role of the propeptides has been studied extensively; however, the role of the Gla domain in substrate binding is less well understood. We used kinetic and fluorescence techniques to investigate the interactions of the carboxylase with a substrate containing the propeptide and Gla domain of factor IX (FIXproGla41). In addition, we characterized the effect of the Gla domain and carboxylation on propeptide and substrate binding. For the propeptide of factor IX (proFIX18), FIXproGla41, and carboxylated FIXproGla41, the Kd values were 50, 2.5, and 19.7 nM and the koff values were 273 x 10(-5), 9 x 10(-5), and 37 x 10(-5) s(-1), respectively. The koff of proFIX18 is reduced 3-fold by FLEEL and 9-fold by the Gla domain (residues 1-46) of FIX. The pre-steady state rate constants for carboxylation of FIXproGla41 was 0.02 s(-1) in enzyme excess and 0.016 s(-1) in substrate excess. The steady state rate in substrate excess is 4.5 x 10(-4) s(-1). These results demonstrate the following. 1) The pre-steady state carboxylation rate constant of FIXproGla41 is significantly slower than that of FLEEL. 2) The Gla domain plays an allosteric role in substrate-enzyme interactions. 3) Carboxylation reduces the allosteric effect. 4) The similarity between the steady state carboxylation rate constant and product dissociation rate constant suggests that product release is rate-limiting. 5) The increased dissociation rate after carboxylation contributes to the release of product.     

Insight into the coupling mechanism of the vitamin K-dependent carboxylase: mutation of histidine 160 disrupts glutamic acid carbanion formation and efficient coupling of vitamin K epoxidation to glutamic acid carboxylation

Vitamin K-dependent (VKD) proteins become activated by the VKD carboxylase, which converts Glu's to carboxylated Glu's (Gla's) in their Gla domains. The carboxylase uses vitamin K epoxidation to drive Glu carboxylation, and the two half-reactions are coupled in 1:1 stoichiometry by an unknown mechanism. We now report the first identification of a residue, His160, required for coupling. A H160A mutant showed wild-type levels of epoxidation but substantially less carboxylation. Monitoring proton abstraction using a peptide with Glu tritiated at the gamma-carbon position revealed that poor coupling was due to impaired carbanion formation. H160A showed a 10-fold lower ratio of tritium release to vitamin K epoxidation than wild-type enzyme (i.e., 0.12 versus 1.14, respectively), which could fully account for the fold decrease in coupling efficiency. The Ala substitution in His160 did not affect the K m for vitamin K and caused only a 2-fold increase in the K m for Glu and 2-fold decrease in the activation of vitamin K epoxidation by Glu. The H160A K m for CO 2 was 5-fold higher than the wild-type enzyme. However, the k cat for H160A carboxylation was 8-9-fold lower than the wild-type enzyme with all three substrates (i.e., Glu, CO 2, and vitamin K), suggesting a catalytic role for His160 in carbanion formation. We propose that His160 facilitates the formation of the transition state for carbanion formation. His160 is highly conserved in metazoan VKD carboxylases but not in some bacterial orthologues (acquired by horizontal gene transfer), which has implications for how bacteria have adapted the carboxylase for novel functions.     

Identification of a Drosophila vitamin K-dependent gamma-glutamyl carboxylase

Using reduced vitamin K, oxygen, and carbon dioxide, gamma-glutamyl carboxylase post-translationally modifies certain glutamates by adding carbon dioxide to the gamma position of those amino acids. In vertebrates, the modification of glutamate residues of target proteins is facilitated by an interaction between a propeptide present on target proteins and the gamma-glutamyl carboxylase. Previously, the gastropod Conus was the only known invertebrate with a demonstrated vitamin K-dependent carboxylase. We report here the discovery of a gamma-glutamyl carboxylase in Drosophila. This Drosophila enzyme is remarkably similar in amino acid sequence to the known mammalian carboxylases; it has 33% sequence identity and 45% sequence similarity to human gamma-glutamyl carboxylase. The Drosophila carboxylase is vitamin K-dependent, and it has a K(m) toward a model pentapeptide substrate, FLEEL, of about 4 mm. However, unlike the human gamma-glutamyl carboxylase, it is not stimulated by human blood coagulation factor IX propeptides. We found the mRNA for Drosophila gamma-glutamyl carboxylase in virtually every embryonic and adult stage that we investigated, with the highest concentration evident in the adult head.     

The putative vitamin K-dependent gamma-glutamyl carboxylase internal propeptide appears to be the propeptide binding site

The vitamin K-dependent gamma-glutamyl carboxylase binds an 18-amino acid sequence usually attached as a propeptide to its substrates. Price and Williamson (Protein Sci. (1993) 2, 1997-1998) noticed that residues 495-513 of the carboxylase shares similarity with the propeptide. They suggested that this internal propeptide could bind intramolecularly to the propeptide binding site of carboxylase, thereby preventing carboxylation of substrates lacking a propeptide recognition sequence. To test Price's hypothesis, we created nine mutant enzyme species that have single or double mutations within this putative internal propeptide. The apparent K(d) values of these mutant enzymes for human factor IX propeptide varied from 0.5- to 287-fold when compared with that of wild type enzyme. These results are consistent with the internal propeptide hypothesis but could also be explained by these residues participating in propeptide binding site per se. To distinguish between the two alternative hypotheses, we measured the dissociation rates of propeptides from each of the mutant enzymes. Changes in an internal propeptide should not affect the dissociation rates, but changes to a propeptide binding site may affect the dissociation rate. We found that dissociation rates varied in a manner consistent with the apparent K(d) values measured above. Furthermore, kinetic studies using propeptide-containing substrates demonstrated a correlation between the affinity for propeptide and V(max). Taken together, our results indicated that these mutations affected the propeptide binding site rather than a competitive inhibitory internal propeptide sequence. These results agree with our previous observations, indicating that residues in this region are involved in propeptide binding.     

Identification of sequences within the gamma-carboxylase that represent a novel contact site with vitamin K-dependent proteins and that are required for activity

The vitamin K-dependent (VKD) carboxylase converts clusters of Glu residues to gamma-carboxylated Glu residues (Glas) in VKD proteins, which is required for their activity. VKD precursors are targeted to the carboxylase by their carboxylase recognition site, which in most cases is a propeptide. We have identified a second tethering site for carboxylase and VKD proteins that is required for carboxylase activity, called the vitamin K-dependent protein site of interaction (VKS). Several VKD proteins specifically bound an immobilized peptide comprising amino acids 343-355 of the human carboxylase (CVYKRSRGKSGQK) but not a scrambled peptide containing the same residues in a different order. Association with the 343-355 peptide was independent of propeptide binding, because the VKD proteins lacked the propeptide and because the 343-355 peptide did not disrupt association of a propeptide factor IX-carboxylase complex. Analysis with peptides that overlapped amino acids 343-355 indicated that the 343-345 CVY residues were necessary but not sufficient for prothrombin binding. Ionic interactions were also suggested because peptide-VKD protein binding could be disrupted by changes in ionic strength or pH. Mutagenesis of Cys(343) to Ser and Tyr(345) to Phe resulted in 7-11-fold decreases in vitamin K epoxidation and peptide (EEL) substrate and carboxylase carboxylation, and kinetic analysis showed 5-6-fold increases in K(m) values for the Glu substrate. These results suggest that Cys(343) and Tyr(345) are near the catalytic center and affect the active site conformation required for correct positioning of the Glu substrate. The 343-355 VKS peptide had a higher affinity for carboxylated prothrombin (K(d) = 5 microm) than uncarboxylated prothrombin (K(d) = 60 microm), and the basic VKS region may also facilitate exiting of the Gla product from the catalytic center by ionic attraction. Tethering of VKD proteins to the carboxylase via the propeptide-binding site and the VKS region has important implications for the mechanism of VKD protein carboxylation, and a model is proposed for how the carboxylase VKS region may be required for efficient and processive VKD protein carboxylation.     

Vitamin K-dependent carboxylation. A synthetic peptide based upon the gamma-carboxylation recognition site sequence of the prothrombin propeptide is an active substrate for the carboxylase in vitro

The vitamin K-dependent blood-clotting proteins contain a gamma-carboxylation recognition site in the propeptide, between the signal peptide and the mature protein, that directs gamma-carboxylation of specific glutamic acid residues. To develop a better substrate for the in vitro assay of the vitamin K-dependent gamma-carboxylase and to understand the substrate recognition requirements of the carboxylase, we prepared synthetic peptides based upon the structure of human proprothrombin. These peptides were employed as substrates for in vitro carboxylation using a partially purified form of the bovine liver carboxylase. A 28-residue peptide (HVFLAPQQARSLLQRVRRANTFLEEVRK), based on residues -18 to +10 in proprothrombin, includes the complete propeptide and the first 10 residues of acarboxyprothrombin. Carboxylation of this peptide is characterized by a Km of 3.6 microM. In contrast, FLEEL is carboxylated with a Km of about 2200 microM. A 10-residue peptide (ANTFLEEVRK), based on residues +1 to +10 in prothrombin, and a 20-residue peptide (ARSLLQRVRRANTFLEEVRK), based on residues -10 to +10 in proprothrombin, are also poor substrates for the carboxylase. Replacement of phenylalanine with alanine at residue 3 (equivalent to position -16 in proprothrombin) in the 28-residue peptide significantly alters the Km to 200 microM. A synthetic propeptide (HVFLAPQQARSLLQRVRRY), homologous to residues -18 to -1 in proprothrombin, inhibited carboxylation of the 28-residue peptide substrate with a Ki of 3.5 microM, but modestly stimulated the carboxylation of the 5- and 10-residue peptide substrates. These results indicate that an intact carboxylation recognition site is required for efficient in vitro carboxylation and that this site includes critical residues in region -18 to -11 of proprothrombin. The carboxylation recognition site in the propeptide binds directly to the carboxylase or to a closely associated protein.     

A novel fluorescence assay to study propeptide interaction with gamma-glutamyl carboxylase

The vitamin K-dependent gamma-glutamyl carboxylase catalyzes the posttranslational modification of select glutamate residues of its vitamin K-dependent substrates to gamma-carboxyglutamate. In this report, we describe a new fluorescence assay that is sensitive and specific for the propeptide binding site of active carboxylase. We employed the assay to make three important observations: (1) A tight binding fluorescein-labeled consensus propeptide can be used to quantify the active fraction of the enzyme. (2) The off-rate for a fluorescein-labeled factor IX propeptide was 3000-fold slower than the rate of carboxylation, a difference that may explain how carboxylase can carry out multiple carboxylations of a substrate during the same binding event. (3) We show evidence that substrate binding to the active site modifies the propeptide binding site of carboxylase. The significant (9-fold) differences in off-rates for the propeptide in the presence and absence of its co-substrates may represent a release mechanism for macromolecular substrates from the enzyme. Additionally, sedimentation velocity and equilibrium experiments indicate a monomeric association of enzyme with propeptide. Furthermore, the carboxylase preparation is monodisperse in the buffer used for our studies.     

Brønsted analysis reveals Lys218 as the carboxylase active site base that deprotonates vitamin K hydroquinone to initiate vitamin K-dependent protein carboxylation

The vitamin K-dependent (VKD) carboxylase converts Glu's to carboxylated Glu's in VKD proteins to render them functional in a broad range of physiologies. The carboxylase uses vitamin K hydroquinone (KH(2)) epoxidation to drive Glu carboxylation, and one of its critical roles is to provide a catalytic base that deprotonates KH(2) to allow epoxidation. A long-standing model invoked Cys as the catalytic base but was ruled out by activity retention in a mutant where every Cys is substituted by Ala. Inhibitor analysis of the cysteine-less mutant suggested that the base is an activated amine [Rishavy et al. (2004) Proc. Natl. Acad. Sci. U.S.A. 101, 13732-13737], and in the present study, we used an evolutionary approach to identify candidate amines, which revealed His160, His287, His381, and Lys218. When mutational analysis was performed using an expression system lacking endogenous carboxylase, the His to Ala mutants all showed full epoxidase activity but K218A activity was not detectable. The addition of exogenous amines restored K218A activity while having little effect on wild type carboxylase, and pH studies indicated that rescue was dependent upon the basic form of the amine. Importantly, Br?nsted analysis that measured the effect of amines with different pK(a) values showed that K218A activity rescue depended upon the basicity of the amine. The combined results provide strong evidence that Lys218 is the essential base that deprotonates KH(2) to initiate the reaction. The identification of this base is an important advance in defining the carboxylase active site and has implications regarding carboxylase membrane topology and the feedback mechanism by which the Glu substrate regulates KH(2) oxygenation.     

Effect of propeptide amino acid substitution in γ‐carboxylation,activity and expression of recombinant human coagulation factor IX

The production of recombinant vitamin K dependent (VKD) proteins for therapeutic purposes is an important challenge in the pharmaceutical industry. These proteins are primarily synthesized as precursor molecules and contain pre–propeptide sequences. The propeptide is connected to γ‐carboxylase enzyme through the γ‐carboxylase recognition site for the direct γ‐carboxylation of VKD proteins that has a significant impact on their biological activity. Propeptides have different attitudes toward γ‐carboxylase and certain amino acids in propeptide sequences are responsible for the differences in γ‐carboxylase affinity. By aiming to replace amino acids in hFIX propeptide domain based on the prothrombin propeptide, pMT‐hFIX‐M14 expression cassette, containing cDNA of hFIX with substituted ?14 residues (Asp to Ala) was made. After transfection of Drosophila S2 cells, expression of the active hFIX was analyzed by performing ELISA and coagulation test. A 1.4‐fold increase in the mutant recombinant hFIX expression level was observed in comparison with that of a native recombinant hFIX. The enhanced hFIX activity and specific activity of the hFIXD‐14A (2.2 and 1.6 times, respectively) were further confirmed by comparing coagulation activity levels of substituted and native hFIX. Enrichment for functional, fully γ‐carboxylated hFIX species via barium citrate adsorption demonstrated 2‐fold enhanced recovery in the S2‐expressing hFIXD‐14A relative to that expressed native hFIX. These results show that changing ?14 residues leads to a decrease in the binding affinity to substrate, increase in γ‐carboxylation and activity of recombinant hFIX. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 34:515–520, 2018     

In vitro gamma-carboxylation of a 59-residue recombinant peptide including the propeptide and the gamma-carboxyglutamic acid domain of coagulation factor IX. Effect of mutations near the propeptide cleavage site

We report the expression in Escherichia coli of a fusion protein that contains the propeptide sequence and gamma-carboxyglutamic acid domain (residues -18 to 41) of human factor IX (FIXGla). CNBr was used to release FIXGla from the fusion protein. The 59-amino acid peptide is an efficient substrate for in vitro gamma-carboxylation. Its Km,app (0.55 microM) is several thousand-fold lower than that of the commonly used substrate FLEEL and about 5 times lower than proPT28 or proFIX28, (Hubbard, B. R., Jacobs, M., Ulrich, M. M. W., Walsh, C., Furie, B., and Furie, B. C. (1989) J. Biol. Chem. 264, 14145-14150). In addition, FIXGla is the first peptide substrate that is carboxylated in vitro to more than one gamma-carboxyglutamic acid/molecule (6-11 gamma-carboxyglutamic acids/molecule). We created peptides with mutations identical to FIXSan Dimas or FIXCambridge as well as a peptide with both mutations in the propeptide sequence and examined the effect of the mutations on in vitro carboxylation. Enzyme kinetic studies revealed no significant difference in Vmax/Km values between normal and mutant substrates. Maximum carbon dioxide incorporation was achieved with the double mutant. From these data we conclude the following. 1) FIXGla and its mutants are excellent substrates for studying the mechanism of gamma-carboxylase. 2) Although arginines at positions -4 and -1 are highly conserved in the propeptide sequence of all the vitamin K-dependent proteins, neither is critical for gamma-carboxylation.     

Carboxylase overexpression effects full carboxylation but poor release and secretion of factor IX: implications for the release of vitamin K-dependent proteins

Vitamin K-dependent (VKD) proteins are modified by the VKD carboxylase as they transit through the endoplasmic reticulum. In a reaction required for their activity, clusters of Glu's are converted to Gla's, and fully carboxylated VKD proteins are normally secreted. In mammalian cell lines expressing high levels of r-VKD proteins, however, under- and uncarboxylated VKD forms are observed. Overexpression of r-carboxylase does not improve carboxylation, but the lack of effect is not understood, and the intracellular events that occur during VKD protein carboxylation have not been investigated. We analyzed carboxylation in 293- and BHK cell lines expressing r-factor IX (fIX) and endogenous carboxylase or overexpressed r-carboxylase. The fIX secreted from the four cell lines was highly carboxylated, indicating fIX-carboxylase engagement during intracellular trafficking. The r-carboxylase was functional for carboxylation: overexpression resulted in a proportional increase in fIX-carboxylase complexes that yielded full fIX carboxylation. Interestingly, the carboxylated fIX product was not efficiently released from the carboxylase in r-fIX/r-carboxylase cells, resulting in decreased fIX secretion. r-Carboxylase overexpression changed the ratios of intracellular fIX to carboxylase, and we therefore developed an in vitro assay to test whether fIX levels affect release. FIX-carboxylase complexes were in vitro carboxylated with or without excess VKD substrate or propeptide. These analyses are the first to dissect the rates of release versus carboxylation and showed that release was much slower than carboxylation. In the absence of excess VKD substrate/propeptide, fIX in the fIX-carboxylase complex was fully carboxylated by 10 min, but 95% was still complexed with carboxylase after 30 min. The presence of excess VKD substrate/propeptide, however, led to a significant increase in VKD product release, possibly through a second propeptide binding site in the carboxylase. The intracellular analyses also showed that the fIX carboxylation rate was slow in vivo and was similar in r-fIX versus r-fIX/r-carboxylase cells, despite the large differences in carboxylase levels. The results suggest that the vitamin K cofactor may be limiting for carboxylation in the cell lines.     

Vitamin K-dependent carboxylation. In vitro modification of synthetic peptides containing the gamma-carboxylation recognition site

Synthetic peptides including the gamma-carboxylation recognition site and acidic amino acids were compared as substrates for vitamin K-dependent gamma-carboxylation by bovine liver carboxylase. The 28-residue proPT28 (proprothrombin -18 to +10) and proFIX28 (pro-Factor IX -18 to +10) were carboxylated with a Km of 3 microM. The Vmax of proPT28 was 2-3 times greater than that of proFIX28. An analog of proFIX28 that contained the prothrombin propeptide had a Vmax 2-3-fold greater than an analog of proPT28 that contained the Factor IX propeptide. proFIX28/RS-1, based upon Factor IX Cambridge, proFIX28/RQ-4, based upon Factor IX Oxford 3, and proFIX28 had equivalent Km and Vmax values. Analogs of proPT28 containing Ala6-Glu7 or Glu6-Ala7 were carboxylated at equivalent rates. A peptide containing Asp6-Asp7 was carboxylated at a rate of about 1% of that of Glu carboxylation. Carboxylation of peptides containing Asp6-Glu7 and Glu6-Asp7 yielded results identical with peptides containing Ala6-Glu7 and Glu6-Ala7. Carboxymethylcysteine was not carboxylated when substituted for Glu6 in a peptide containing Asp7. These results indicate that the prothrombin propeptide is more efficient in the carboxylation process than is the Factor IX propeptide, but that both propeptides direct carboxylation; the gamma-carboxylation recognition site does not include residues -4 and -1; aspartic acid and carboxymethylcysteine are poor substrates for the carboxylase, but aspartic acid does not inhibit the carboxylation of adjacent glutamic acids.     

Tethered processivity of the vitamin K-dependent carboxylase: factor IX is efficiently modified in a mechanism which distinguishes Gla's from Glu's and which accounts for comprehensive carboxylation in vivo

The vitamin K-dependent (VKD) carboxylase binds VKD proteins via their propeptide and converts Glu's to gamma-carboxylated Glu's, or Gla's, in the Gla domain. Multiple carboxylation is required for activity, which could be achieved if the carboxylase is processive. In the only previous study to test for this capability, an indirect assay was used which suggested processivity; however, the efficiency was poor and raised questions regarding how full carboxylation is accomplished. To unequivocally determine if the carboxylase is processive and if it can account for comprehensive carboxylation in vivo, as well as to elucidate the enzyme mechanism, we developed a direct test for processivity. The in vitro carboxylation of a complex containing carboxylase and full-length factor IX (fIX) was challenged with an excess amount of a distinguishable fIX variant. Remarkably, carboxylation of fIX in the complex was completely unaffected by the challenge protein, and comprehensive carboxylation was achieved, showing conclusively that the carboxylase is processive and highly efficient. These studies also showed that carboxylation of individual fIX/carboxylase complexes was nonsynchronous and implicated a driving force for the reaction which requires the carboxylase to distinguish Glu's from Gla's. We found that the Gla domain is tightly associated with the carboxylase during carboxylation, blocking the access of a small peptide substrate (EEL). The studies describe the first analysis of preformed complexes, and the rate for full-length, native fIX in the complex was equivalent to that of the substrate EEL. Thus, intramolecular movement within the Gla domain to reposition new Glu's for catalysis is as rapid as diffusion-limited positioning of a small substrate, and the Gla domain is not sterically constrained by the rest of the fIX molecule during carboxylation. The rate of carboxylation of fIX in the preformed complex was 24-fold higher than for fIX modified by free carboxylase, which supports carboxylase processivity and which indicates that binding and/or release is the rate-limiting step in protein carboxylation. These data indicate a model of tethered processivity, in which the VKD proteins remain bound to the carboxylase throughout the reaction via their propeptide, while the Gla domain undergoes intramolecular movement to reposition new Glu's for catalysis to ultimately achieve comprehensive carboxylation.     

Identification of the N-linked glycosylation sites of vitamin K-dependent carboxylase and effect of glycosylation on carboxylase function

The vitamin K-dependent carboxylase is an integral membrane protein which is required for the post-translational modification of a variety of vitamin K-dependent proteins. Previous studies have suggested carboxylase is a glycoprotein with N-linked glycosylation sites. In this study, we identify the N-glycosylation sites of carboxylase by mass spectrometric peptide mapping analyses combined with site-directed mutagenesis. Our mass spectrometric results show that the N-linked glycosylation in carboxylase occurs at positions N459, N550, N605, and N627. Eliminating these glycosylation sites by changing asparagine to glutamine caused the mutant carboxylase to migrate faster on SDS-PAGE gels, adding further evidence that these sites are glycosylated. In addition, the mutation studies identified N525, a site that cannot be recovered by mass spectroscopy analysis, as a glycosylation site. Furthermore, the potential glycosylation site at N570 is glycosylated only if all five natural glycosylation sites are simultaneously mutated. Removal of the oligosaccharides by glycosidase from wild-type carboxylase or by elimination of the functional glycosylation sites by site-directed mutagenesis did not affect either the carboxylation or epoxidation activity when the small FLEEL pentapeptide was used as a substrate, suggesting that N-linked glycosylation is not required for the enzymatic function of carboxylase. In contrast, when site N570 and the five natural glycosylation sites were mutated simultaneously, the resulting carboxylase protein was degraded. Our results suggest that N-linked glycosylation is not essential for carboxylase enzymatic activity but is important for protein folding and stability.     

A GDP-fucose-protected, pyridoxal-5'-Phosphate/NaBH(4)-sensitive lys residue common to human alpha1-->3Fucosyltransferases corresponds to Lys(300) in FucT-IV

Human alpha1-->3/4fucosyltransferases (FucTs) contain a common essential pyridoxal-5'-phosphate(PLP)/NaBH(4) reactive, GDP-fucose-protectable Lys. For identification, site-directed mutants at lysines of FucT-IV and -VII were prepared and tested. Non conserved lysine mutants K119Y and K394Q were similar to wild-type FucT-IV. However, mutants of conserved lysines K228R and K300R were distinct. The specific activity of K228R was 2- to 3-fold lower but retained K(m) values for donor and acceptor substrates as wild-type FucT-IV. The specific activity of K300R was reduced over 400-fold with an apparent K(m) for GDP-fucose over 200 microM. FucT-VII mutants K169R and K240R (equivalent to K228R and K300R for FucT-IV, respectively) were inactive. No change in PLP/NaBH(4) sensitivity occurred with K119Y, K228R, and K394Q compared to wild-type FucT-IV. These and previous results (A. L. Sherwood, A. T. Nguyen, J. M. Whitaker, B. A. Macher, M. R. Stroud, and E. H. Holmes, J. Biol. Chem. 273, 25256-25260, 1998) demonstrate that of three conserved lysines in FucT-IV, two (Lys(228) and Lys(283)) are not involved in substrate binding but perhaps in catalysis. The third site, Lys(300), is involved in GDP-fucose binding and PLP/NaBH(4) inactivation.     

The propeptides of the vitamin K-dependent proteins possess different affinities for the vitamin K-dependent carboxylase.

The vitamin K-dependent gamma-glutamyl carboxylase catalyzes the modification of specific glutamates in a number of proteins required for blood coagulation and associated with bone and calcium homeostasis. All known vitamin K-dependent proteins possess a conserved eighteen-amino acid propeptide sequence that is the primary binding site for the carboxylase. We compared the relative affinities of synthetic propeptides of nine human vitamin K-dependent proteins by determining the inhibition constants (Ki) toward a factor IX propeptide/gamma-carboxyglutamic acid domain substrate. The Ki values for six of the propeptides (factor X, matrix Gla protein, factor VII, factor IX, PRGP1, and protein S) were between 2-35 nM, with the factor X propeptide having the tightest affinity. In contrast, the inhibition constants for the propeptides of prothrombin and protein C are approximately 100-fold weaker than the factor X propeptide. The propeptide of bone Gla protein demonstrates severely impaired carboxylase binding with an inhibition constant of at least 200,000-fold weaker than the factor X propeptide. This study demonstrates that the affinities of the propeptides of the vitamin K-dependent proteins vary over a considerable range; this may have important physiological consequences in the levels of vitamin K-dependent proteins and the biochemical mechanism by which these substrates are modified by the carboxylase.     

Novel insights into the biotin carboxylase domain reactions of pyruvate carboxylase from Rhizobium etli

The catalytic mechanism of the MgATP-dependent carboxylation of biotin in the biotin carboxylase domain of pyruvate carboxylase from R. etli (RePC) is common to the biotin-dependent carboxylases. The current site-directed mutagenesis study has clarified the catalytic functions of several residues proposed to be pivotal in MgATP-binding and cleavage (Glu218 and Lys245), HCO(3)(-) deprotonation (Glu305 and Arg301), and biotin enolization (Arg353). The E218A mutant was inactive for any reaction involving the BC domain and the E218Q mutant exhibited a 75-fold decrease in k(cat) for both pyruvate carboxylation and the full reverse reaction. The E305A mutant also showed a 75- and 80-fold decrease in k(cat) for both pyruvate carboxylation and the full reverse reaction, respectively. While Glu305 appears to be the active site base which deprotonates HCO(3)(-), Lys245, Glu218, and Arg301 are proposed to contribute to catalysis through substrate binding interactions. The reactions of the biotin carboxylase and carboxyl transferase domains were uncoupled in the R353M-catalyzed reactions, indicating that Arg353 may not only facilitate the formation of the biotin enolate but also assist in coordinating catalysis between the two spatially distinct active sites. The 2.5- and 4-fold increase in k(cat) for the full reverse reaction with the R353K and R353M mutants, respectively, suggests that mutation of Arg353 allows carboxybiotin increased access to the biotin carboxylase domain active site. The proposed chemical mechanism is initiated by the deprotonation of HCO(3)(-) by Glu305 and concurrent nucleophilic attack on the γ-phosphate of MgATP. The trianionic carboxyphosphate intermediate formed reversibly decomposes in the active site to CO(2) and PO(4)(3-). PO(4)(3-) then acts as the base to deprotonate the tethered biotin at the N(1)-position. Stabilized by interactions between the ureido oxygen and Arg353, the biotin-enolate reacts with CO(2) to give carboxybiotin. The formation of a distinct salt bridge between Arg353 and Glu248 is proposed to aid in partially precluding carboxybiotin from reentering the biotin carboxylase active site, thus preventing its premature decarboxylation prior to the binding of a carboxyl acceptor in the carboxyl transferase domain.     

Evolving improved Synechococcus Rubisco functional expression in Escherichia coli

The photosynthetic CO2-fixing enzyme Rubisco [ribulose-P(2) (D-ribulose-1,5-bisphosphate) carboxylase/oxygenase] has long been a target for engineering kinetic improvements. Towards this goal we used an RDE (Rubisco-dependent Escherichia coli) selection system to evolve Synechococcus PCC6301 Form I Rubisco under different selection pressures. In the fastest growing colonies, the Rubisco L (large) subunit substitutions I174V, Q212L, M262T, F345L or F345I were repeatedly selected and shown to increase functional Rubisco expression 4- to 7-fold in the RDE and 5- to 17-fold when expressed in XL1-Blue E. coli. Introducing the F345I L-subunit substitution into Synechococcus PCC7002 Rubisco improved its functional expression 11-fold in XL1-Blue cells but could not elicit functional Arabidopsis Rubisco expression in the bacterium. The L subunit substitutions L161M and M169L were complementary in improving Rubisco yield 11-fold, whereas individually they improved yield approximately 5-fold. In XL1-Blue cells, additional GroE chaperonin enhanced expression of the I174V, Q212L and M262T mutant Rubiscos but engendered little change in the yield of the more assembly-competent F345I or F345L mutants. In contrast, the Rubisco chaperone RbcX stimulated functional assembly of wild-type and mutant Rubiscos. The kinetic properties of the mutated Rubiscos varied with noticeable reductions in carboxylation and oxygenation efficiency accompanying the Q212L mutation and a 2-fold increase in K(ribulose-P2) (K(M) for the substrate ribulose-P2) for the F345L mutant, which was contrary to the approximately 30% reductions in K(ribulose-P2) for the other mutants. These results confirm the RDE systems versatility for identifying mutations that improve functional Rubisco expression in E. coli and provide an impetus for developing the system to screen for kinetic improvements.