Spectroscopic Characterization of Soybean Lipoxygenase-1 Mutants:  the Role of Second Coordination Sphere Residues in the Regulation of Enzyme Activity

Schenk, Gerhard; Neidig, Michael L.; Zhou, Jing; Holman, Theodore R.; Solomon, Edward I.

doi:10.1021/bi027380g

Cited by 50 publications

(73 citation statements)

References 42 publications

(106 reference statements)

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“…4 and 5) raised the issue of whether this structural change could also be impacting the experimental rate parameters. We consider this explanation highly unlikely for a number of reasons that include: (i) the observation of two configurations for the H499/Q495 hydrogen bonding pair in WT-SLO; (ii) the fact that the full H-bonding network is retained, along with the liganding of H499 to the iron, among all of the mutants; and (iii) the published finding that the Q495E retained full enzyme activity (28).…”

Section: Distinguishing the Types Of Heavy Atom Motions That Impact H-mentioning

confidence: 99%

Enzyme structure and dynamics affect hydrogen tunneling: The impact of a remote side chain (I553) in soybean lipoxygenase-1

Meyer

Tomchick²,

Klinman

2008

Proc. Natl. Acad. Sci. U.S.A.

150

293

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This study examines the impact of a series of mutations at position 553 on the kinetic and structural properties of soybean lipoxygenase-1 (SLO-1). The previously uncharacterized mutants reported herein are I553L, I553V, and I553G. High-resolution x-ray studies of these mutants, together with the earlier studied I553A, show almost no structural change in relation to the WT-enzyme. By contrast, a progression in kinetic behavior occurs in which the decrease in the size of the side chain at position 553 leads to an increased importance of donor–acceptor distance sampling in the course of the hydrogen transfer process. These dynamical changes in behavior are interpreted in the context of two general classes of protein motions, preorganization and reorganization, with the latter including the distance sampling modes [Klinman JP (2006) Philos Trans R Soc London Ser B 361:1323–1331; Nagel Z, Klinman JP (2006) Chem Rev 106:3095–3118]. The aggregate data for SLO-1 show how judicious placement of hydrophobic side chains can influence enzyme catalysis via enhanced donor–acceptor hydrogenic wave function overlap.

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Section: Distinguishing the Types Of Heavy Atom Motions That Impact H-mentioning

confidence: 99%

Enzyme structure and dynamics affect hydrogen tunneling: The impact of a remote side chain (I553) in soybean lipoxygenase-1

Meyer

Tomchick²,

Klinman

2008

Proc. Natl. Acad. Sci. U.S.A.

150

293

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“…Three residues of the second-coordination sphere (35) around the iron coordination sphere, Q784 Q711,Q697 and L842…”

Section: Discussionmentioning

confidence: 99%

Programmed chloroplast destruction during leaf senescence involves 13-lipoxygenase (13-LOX)

Springer

Kang

Rustgi

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Leaf senescence is the terminal stage in the development of perennial plants. Massive physiological changes occur that lead to the shut down of photosynthesis and a cessation of growth. Leaf senescence involves the selective destruction of the chloroplast as the site of photosynthesis. Here, we show that 13-lipoxygenase (13-LOX) accomplishes a key role in the destruction of chloroplasts in senescing plants and propose a critical role of its NH 2 -terminal chloroplast transit peptide. The 13-LOX enzyme identified here accumulated in the plastid envelope and catalyzed the dioxygenation of unsaturated membrane fatty acids, leading to a selective destruction of the chloroplast and the release of stromal constituents. Because 13-LOX pathway products comprise compounds involved in insect deterrence and pathogen defense (volatile aldehydes and oxylipins), a mechanism of unmolested nitrogen and carbon relocation is suggested that occurs from leaves to seeds and roots during fall.chloroplast envelope | membrane destruction | oxylipins | green leaf volatiles | herbivore deterrence D espite considerable progress made over the last few years, little is still known about the molecular mechanism governing plant senescence. Up-regulation of thousands of different genes has been reported (1-3). These so-called senescenceassociated genes (SAGs) encode components active in signal perception, transduction, and execution, as well as hormone homoeostasis (1-3). Genetic and biochemical studies identified several receptor-like kinases, MAP kinase cascades, as well as NAC and WRKY transcription factors as regulating the senescence program (4, 5).During leaf senescence, chloroplasts as sites of photosynthesis undergo massive destruction and finally collapse. Symptoms similar to those observed during natural senescence can be induced by treating leaf tissues with jasmonic acid (JA) and its methyl ester, methyl jasmonate (MeJA), which are widespread plant cyclopentanone compounds with similarities to prostaglandins (see ref. 6 for review). During natural and MeJAinduced senescence, common decreases in the photosynthetic capacity and chlorophyll content have been observed (1-3). Carbon and nitrogen relocation is of fundamental importance for seed filling, and thus mass degradation of photosynthetic constituents needs to be tightly controlled in time and space (7,8). In fact, more than one billion tons of chlorophyll, coming from the disassembled photosynthetic apparatus, needs to be turned over every year (9). Similarly, the key enzyme of photosynthesis, ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCo), has to be degraded (10). Turnover of these key macromolecules is thought to proceed through a tight interaction between senescing chloroplasts, the cytosol, and lytic vacuoles. Several stromal proteases are implicated in the early steps of RuBisCo breakdown (11-13). Degradation of chlorophyll involves numerous, wellcharacterized steps and involves plastid and nonplastid reactions (14). Lytic vacuoles have been implicated in chlorop...

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“…The signals in the EPR spectra and their intensity are a reflection of the detailed interactions of iron and its ligands, and the two signals may correspond to 5-and 6-coordinate iron liganding. Previously, a network of H-bonds involving iron ligand Asn 694 and residues in the iron second coordination sphere has been characterized by mutation, CD, magnetic circular dichroism, and x-ray structure analyses, with the conclusion that dynamic changes in iron coordination, and especially in the iron-Asn 694 bond length, is essential for catalytic function (44,45). It is likely that the helix 11 containing Ala or Gly at 542 is connected through hydrogen bonds of residues and waters in cavity IIa to the network of H-bonds that modulate the iron-ligand bond lengths.…”

Section: Discussionmentioning

confidence: 99%

On the Relationships of Substrate Orientation, Hydrogen Abstraction, and Product Stereochemistry in Single and Double Dioxygenations by Soybean Lipoxygenase-1 and Its Ala542Gly Mutant

Coffa

Imber

Maguire

et al. 2005

Journal of Biological Chemistry

105

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Recent findings associate the control of stereochemistry in lipoxygenase (LOX) catalysis with a conserved active site alanine for S configuration hydroperoxide products, or a corresponding glycine for R stereoconfiguration. To further elucidate the mechanistic basis for this stereocontrol we compared the stereoselectivity of the initiating hydrogen abstraction in soybean LOX-1 and an Ala542Gly mutant that converts linoleic acid to both 13S and 9R configuration hydroperoxide products. Using 11R-3 Hand 11S-3 H-labeled linoleic acid substrates to examine the initial hydrogen abstraction, we found that all the primary hydroperoxide products were formed with an identical and highly stereoselective pro-S hydrogen abstraction from C-11 of the substrate (97-99% pro-S-selective). This strongly suggests that 9R and 13S oxygenations occur with the same binding orientation of substrate in the active site, and as the equivalent 9R and 13S products were formed from a bulky ester derivative (1-palmitoyl-2-linoleoylphosphatidylcholine), one can infer that the orientation is tail-first. Both the EPR spectrum and the reaction kinetics were altered by the R product-inducing Ala-Gly mutation, indicating a substantial influence of this Ala-Gly substitution extending to the environment of the active site iron. To examine also the reversed orientation of substrate binding, we studied oxygenation of the 15S-hydroperoxide of arachidonic acid by the Ala542Gly mutant soybean LOX-1. In addition to the usual 5S,15S-and 8S,15S-dihydroperoxides, a new product was formed and identified by high-performance liquid chromatography, UV, gas chromatography-mass spectrometry, and NMR as 9R,15S-dihydroperoxyeicosa-5Z,7E,11Z,13E-tetraenoic acid, the R configuration "partner" of the normal 5S,15S product. This provides evidence that both tail-first and carboxylate end-first binding of substrate can be associated with S or R partnerships in product formation in the same active site.

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Spectroscopic Characterization of Soybean Lipoxygenase-1 Mutants: the Role of Second Coordination Sphere Residues in the Regulation of Enzyme Activity

Cited by 50 publications

References 42 publications

Enzyme structure and dynamics affect hydrogen tunneling: The impact of a remote side chain (I553) in soybean lipoxygenase-1

Enzyme structure and dynamics affect hydrogen tunneling: The impact of a remote side chain (I553) in soybean lipoxygenase-1

Programmed chloroplast destruction during leaf senescence involves 13-lipoxygenase (13-LOX)

On the Relationships of Substrate Orientation, Hydrogen Abstraction, and Product Stereochemistry in Single and Double Dioxygenations by Soybean Lipoxygenase-1 and Its Ala542Gly Mutant

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