Deregulation of phenylalanine biosynthesis evolved with the emergence of vascular plants.

Phenylalanine (Phe) is the precursor of essential secondary products in plants. Here we show that a key, rate-limiting step in Phe biosynthesis, which is catalyzed by arogenate dehydratase, experienced feedback de-regulation during evolution. Enzymes from microorganisms and type-I ADTs from plants are strongly feedback-inhibited by Phe, while type-II isoforms remain active at high levels of Phe. We have found that type-II ADTs are widespread across seed plants and their overproduction resulted in a dramatic accumulation of Phe in planta, reaching levels up to 40 times higher than those observed following the expression of type-I enzymes. Punctual changes in the allosteric binding site of Phe and adjacent region are responsible for the observed relaxed regulation. The phylogeny of plant ADTs evidences that the emergence of type-II isoforms with relaxed regulation occurred at some point in the transition between nonvascular plants and tracheophytes, enabling the massive production of Phe-derived compounds, primarily lignin, a hallmark of vascular plants.

Accessing p-Hydroxycinnamic Acids: Chemical Synthesis, Biomass Recovery, or Engineered Microbial Production?

p-Hydroxycinnamic acids (i. e., p-coumaric, ferulic, sinapic, and caffeic acids) are phenolic compounds involved in the biosynthesis pathway of lignin. These naturally occurring molecules not only exhibit numerous attractive properties, such as antioxidant, anti-UV, and anticancer activities, but they also have been used as building blocks for the synthesis of tailored monomers and functional additives for the food/feed, cosmetic, and plastics sectors. Despite their numerous high value-added applications, the sourcing of p-hydroxycinnamic acids is not ensured at the industrial scale except for ferulic acid, and their production cost remains too high for commodity applications. These compounds can be either chemically synthesized or extracted from lignocellulosic biomass, and recently their production through bioconversion emerged. Herein the different strategies described in the literature to produce these valuable molecules are discussed.

Neuroprotection of hydroxysafflor yellow A in experimental cerebral ischemia/reperfusion injury via metabolic inhibition of phenylalanine and mitochondrial biogenesis.

Stroke is the second most frequent cause of mortality, resulting in a huge societal burden worldwide. Timely reperfusion is the most effective therapy; however, it is difficult to prevent ischemia/reperfusion (I/R) injury. In traditional Chinese medicine, hydroxysafflor yellow A (HSYA) has been widely used for the treatment of cerebrovascular disease and as a protective therapy against I/R injury. Evidence has demonstrated that HSYA could reduce the levels of reactive oxygen species and suppress cellular apoptosis; however, whether HSYA alters the metabolic profile as its underlying mechanism for neuroprotection remains unknown. In the present study, using a metabolomic screening, phenylalanine was identified to significantly increase in an experimental model of mouse cerebral I/R injury. Notably, western blotting and qPCR analysis were conducted to test the expression level of apoptosis­associated factors, and HSYA was identified to be able to protect neuronal cells by reducing phenylalanine level associated with I/R injury. Additionally, these findings were confirmed in primary mouse neurons and PC12 cells exposed to oxygen and glucose deprivation/reoxygenation (OGD/R) stress. Of note, HSYA was observed to regulate the mRNA expression of key metabolic enzymes, phenylalanine hydroxylase, tyrosine aminotransferase and aspartate aminotransferase, which are responsible for phenylalanine metabolism. Furthermore, by performing mitochondrial labeling and JC­1 fluorescence assay, HSYA was identified to promote mitochondrial function and biogenesis suppressed by OGD/R. The findings of the present study demonstrated that I/R injury could increase the levels of phenylalanine, and HSYA may inhibit phenylalanine synthesis to enhance mitochondrial function and biogenesis for neuroprotection. The present study proposed a novel metabolite biomarker for cerebral I/R injury and the evaluated the efficacy of HSYA as a potential therapeutic treatment I/R injury.

A Myb transcription factor regulates genes of the phenylalanine pathway in maritime pine.

During the life cycles of conifer trees, such as maritime pine (Pinus pinaster Ait.), large quantities of carbon skeletons are irreversibly immobilized in the wood. In energetic terms this is an expensive process, in which carbon from photosynthesis is channelled through the shikimate pathway for the biosynthesis of phenylpropanoids. This crucial metabolic pathway is finely regulated, primarily through transcriptional control, and because phenylalanine is the precursor for phenylpropanoid biosynthesis, the precise regulation of phenylalanine synthesis and use should occur simultaneously. The promoters of three genes encoding the enzymes prephenate aminotransferase (PAT), phenylalanine ammonia lyase (PAL) and glutamine synthetase (GS1b) contain AC elements involved in the transcriptional activation mediated by R2R3-Myb factors. We have examined the capacity of the R2R3-Myb transcription factors Myb1, Myb4 and Myb8 to co-regulate the expression of PAT, PAL and GS1b. Only Myb8 was able to activate the transcription of the three genes. Moreover, the expression of this transcription factor is higher in lignified tissues, in which a high demand for phenylpropanoids exits. In a gain-of-function experiment, we have shown that Myb8 can specifically bind a well-conserved eight-nucleotide-long AC-II element in the promoter regions of PAT, PAL and GS1b, thereby activating their expression. Our results show that Myb8 regulates the expression of these genes involved in phenylalanine metabolism, which is required for channelling photosynthetic carbon to promote wood formation. The co-localization of PAT, PAL, GS1b and MYB8 transcripts in vascular cells further supports this conclusion.

Adequate phenylalanine synthesis mediated by G protein is critical for protection from UV radiation damage in young etiolated Arabidopsis thaliana seedlings.

Etiolated Arabidopsis thaliana seedlings, lacking a functional prephenate dehydratase1 gene (PD1), also lack the ability to synthesize phenylalanine (Phe) and, as a consequence, phenylpropanoid pigments. We find that low doses of ultraviolet (UV)-C (254 nm) are lethal and low doses of UV-B cause severe damage to etiolated pd1 mutants, but not to wild-type (wt) seedlings. Furthermore, exposure to UV-C is lethal to etiolated gcr1 (encoding a putative G protein-coupled receptor in Arabidopsis) mutants and gpa1 (encoding the sole G protein alpha subunit in Arabidopsis) mutants. Addition of Phe to growth media restores wt levels of UV resistance to pd1 mutants. The data indicate that the Arabidopsis G protein-signalling pathway is critical to providing protection from UV, and does so via the activation of PD1, resulting in the synthesis of Phe. Cotyledons of etiolated pd1 mutants have proplastids (compared with etioplasts in wt), less cuticular wax and fewer long-chain fatty acids. Phe-derived pigments do not collect in the epidermal cells of pd1 mutants when seedlings are treated with UV, particularly at the cotyledon tip. Addition of Phe to the growth media restores a wt phenotype to pd1 mutants.

Regulation of aroP expression by tyrR gene in Escherichia coli.

tyrR gene encodes a global regulatory protein (TyrR), which plays an important role in the transcriptional regulation of eight transcription units (including tyrR gene itself) whose protein products catalyze key steps in aromatic amino acid biosynthesis and/or transport. The aroP gene encodes an integral membrane protein (AroP) that transports aromatic amino acids through the cell membrane. The transcription of aroP was reported to be repressed by TyrR. In this work, aroP(p) (aroP gene carrying its own promoter), aroP (aroP gene without promoter) and tyrR genes were amplified by PCR from genomic DNA of E. coli K12 and introduced into E. coli WT5. The expression of aroP and tyrR were detected and the activities of AroP and TyrR were determined. The introduction of either aroP(p) or aroP elevated the strain's transport activity by 1.40 or 1.46-fold respectively. Transformant carrying tyrR gene showed an ATPase activity 1.69-fold compared with the control. When the genes were linked in tandem and co-expressed in a plasmid, the relative AroP transport activity of the strain harboring aroP(p) -tyrR (0.95) was significantly lower than that of aroP-tyrR (1.31). The results indicated that TyrR might be able to reduce the expression of aroP gene by binding with the aroP promoter region in E.coli.

Characterization of sparsomycin resistance in Streptomyces sparsogenes.

The antitumor antibiotic sparsomycin, produced by Streptomyces sparsogenes, is a universal translation inhibitor that blocks the peptide bond formation in ribosomes from all species. Sparsomycin-resistant strains were selected by transforming the sensitive Streptomyces lividans with an S. sparsogenes library. Resistance was linked to the presence of a plasmid containing an S. sparsogenes 5.9-kbp DNA insert. A restriction analysis of the insert traced down the resistance to a 3.6-kbp DNA fragment, which was sequenced. The analysis of the fragment nucleotide sequence together with the previous restriction data associate the resistance to srd, an open reading frame of 1,800 nucleotides. Ribosomes from S. sparsogenes and the S. lividans-resistant strains are equally sensitive to the inhibitor and bind the drug with similar affinity. Moreover, the drug was not modified by the resistant strains. However, resistant cells accumulated less antibiotic than the sensitive ones. In addition, membrane fractions from the resistant strains showed a higher capacity for binding the drug. The results indicate that resistance in the producer strain is not connected to either ribosome modification or drug inactivation, but it might be related to an alteration in the sparsomycin permeability barrier.

Characterisation of Saccharomyces cerevisiae ARO8 and ARO9 genes encoding aromatic aminotransferases I and II reveals a new aminotransferase subfamily.

The ARO8 and ARO9 genes of Saccharomyces cerevisiae were isolated by complementation of the phenylalanine/tyrosine auxotrophy of an aro8 and aro9 double-mutant strain that is defective in aromatic aminotransferase I (aro8) and II (aro9). The genes were sequenced, and deletion mutants were constructed and analysed. The expression of ARO8 and ARO9 was studied. The deduced amino acid sequences of Aro8p and Aro9p suggest that the former is a 500-residue, 56168-Da polypeptide and the latter a 513-residue, 58516-Da polypeptide. They correspond, respectively, to Ygl202p and Yhr137p, two putative proteins of unknown function revealed by systematic sequencing of the yeast genome. We show that aromatic aminotransferases I and II are homologous proteins, members of aminotransferase subgroup I, and, together with three other proteins, they constitute within the subgroup a new subfamily of enzymes specialised for aromatic amino acid and alpha-aminoadipate transamination. ARO8 expression is subject to the general control of amino acid biosynthesis. ARO9 expression is induced when aromatic amino acids are present in the growth medium and also in aro8 mutants grown on minimal ammonia medium. An autonomously replicating sequence (ARS) element is located between the ARO8 gene and YGL201c which encodes a protein of the minichromosome maintenance family.

Metabolic consequences of phosphotransferase (PTS) mutation in a phenylalanine-producing recombinant Escherichia coli.

E. coli strain PPA305, which has a wild-type PTS system, and PPA316, which utilizes a proton-galactose symport system for glucose uptake, were used as host strains to harbor a phenylalanine overproduction plasmid pSY130-14 and to study the effects of using different glucose uptake systems on phenylalanine production. The non-PTS strain (PPA316/pSY130-14) produced much less phenylalanine, ranging from 0 to 67% of that produced by the PTS strain (PPA305/pSY130-14) depending on cultivation conditions used. The non-PTS strain PPA316/pSY130-14 had an intracellular PEP concentration only one-sixth that of the PTS strain, PPA305/pSY130-14. Additionally, PPA316/pSY130-14 had a substantially lower energy state in terms of the size of the pool of high-energy phosphate compounds and the magnitude of the pH difference across the cytoplasmic membrane. The non-PTS strain consumed oxygen at a higher rate, attained lower biomass concentration, and produced no acetate and phenylalanine during fermentation, suggesting more carbon was oxidized to CO2, most likely through the TCA cycle. Analysis of intracellular fluxes through the central carbon pathways was performed for each strain utilizing exponential phase data on extracellular components and assuming quasi-steady state for intermediate metabolites. The non-PTS strain had a higher flux through pyruvate kinase (PYK) and TCA cycle which, in agreement with the observed higher oxygen uptake rate, suggests that more carbon was oxidized to CO2 through the TCA cycle. Further analysis using rate expression data for PYK and NMR data for the intracellular metabolites identified the regulatory properties of PYK as the probable cause for lower intracellular PEP levels in PPA316/pSY130-14.

Mutational analysis of the feedback sites of phenylalanine-sensitive 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase of Escherichia coli.

In Escherichia coli, aroF, aroG, and aroH encode 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase isozymes that are feedback inhibited by tyrosine, phenylalanine, and tryptophan, respectively. In vitro chemical mutagenesis of the cloned aroG gene was used to identify residues and regions of the polypeptide essential for phenylalanine feedback inhibition.

Methylation of the conserved A1518-A1519 in Escherichia coli 16S ribosomal RNA by the ksgA methyltransferase is influenced by methylations around the similarly conserved U1512.G1523 base pair in the 3' terminal hairpin.

An in vitro system developed for the site-specific mutagenesis of 16S rRNA of Escherichia coli ribosomes was used to make five mutations around the highly conserved U1512.G1523 base pair in the 3' terminal hairpin. Each of the mutant RNAs was reconstituted with a complete mixture of 30S proteins to yield 30S ribosomal particles, which were tested for the ability of the ksgA methylase to form m6(2)A1518 and m6(2)A1519. Dimethylation of A1518 and A1519 in the hairpin loop was inhibited 20-80% by the mutations. The results indicate that G1523 and C1524 in the stem are important determinants for the dimethylation of A1518 and A1519 in the loop. Either the enzyme recognition region extends that far or the effect of mutations in the stem are propagated in some manner to the loop. The conserved U.G base pair does not of itself appear to play a major role in ksgA methylase recognition.

[Isolation of ribosomal subparticles from human placenta containing intact rRNA and determination of the functional activity of the 80S ribosome]. / Vydelenie ribosomykh subchastits iz platsenty cheloveka, soderzhashchikh intaktnuiu rRNK, i opredelenie funktsional'noi aktivnosti 80S ribosom.

The method for isolation of human placenta ribosomal subunits containing intact rRNA has been determined. The method uses fresh unfrozen placenta. Activity of 80S ribosomes obtained via reassociation of 40S and 60S subunits in non-enzymatic poly(U)-mediated Phe-tRNAPhe binding, was near 75% (maximal [14C]Phe-tRNA(Phe) binding was 1.5 mol Phe-tRNA(Phe) per mol of 80S ribosomes). Activity of 80S ribosomes with damaged rRNA isolated from frozen placenta was 2 times lower (the maximum level of poly(U)-dependent Phe-tRNA(Phe) binding was 0.7 mol per mol of ribosomes). The activity 80S ribosomes in poly(U)-mediated synthesis of polyphenylalanine was determined by using fractionated ("ribosomeless") protein synthesising system from rabbit reticulocytes. In this system up to the 50 mol of Phe residues per mol of 80S ribosomes are incorporated in acid insoluble fraction in 1 hour, at 37 degrees C. The obtained level of [14C]phenylalanine incorporation is three times as much as the amount of Phe residues observed for the ribosomal subunits, isolated from frozen placenta.

Ribosomes of the extremely thermophilic eubacterium Thermotoga maritima are uniquely insensitive to the miscoding-inducing action of aminoglycoside antibiotics.

Poly(U)- and poly(UG)-programmed cell-free systems were developed from the extreme thermophilic, anaerobic eubacterium Thermotoga maritima, and their susceptibility to aminoglycoside and other antibiotics was assayed at a temperature (75 degrees C) close to the physiological optimum (80 degrees C) for cell growth and in vitro polypeptide synthesis, using a Bacillus stearothermophilus system as the reference. The synthetic capacity of the Thermotoga assay mixture was abolished by the eubacterium-targeted drugs chloramphenicol, thiostrepton, and kirromycin. However, streptomycin, the disubstituted 2-deoxystreptamines (kanamycin, gentamicin, neomycin, and paromomycin), and the monosubstituted 2-deoxystreptamine (hygromycin) all failed to promote translational misreading of poly(U) on Thermotoga ribosomes; they also failed to block polyphenylalanine synthesis at a low (less than 10(-4) M) concentration and did not inhibit Thermotoga cell growth at a high (10 micrograms/ml) concentration even though Thermotoga ribosomes possess the 16S rRNA sequences required for aminoglycoside action. In contrast to the other eubacteria, Thermotoga elongation factor G was also refractory to the steroid inhibitor of peptidyl-tRNA translocation fusidic acid.

Kinetic and regulatory properties of arogenate dehydratase in seedlings of Sorghum bicolor (L.) Moench.

Arogenate dehydratase was purified sixfold from an extract of etiolated seedlings of Sorghum bicolor. Prephenate dehydratase was not detected. The arogenate dehydratase activity displayed hyperbolic substrate kinetics with a KM for arogenate of 0.32 mM. Activity was inhibited competitively by phenylalanine and was stimulated by tyrosine. The low KI for phenylalanine (24 microM) and KA for tyrosine (2.5 microM) indicated a high affinity of the enzyme for these effectors. These results establish the routing of metabolites in phenylalanine biosynthesis in sorghum as proceeding via arogenate rather than phenylpyruvate.

Growth of Paracoccus denitrificans on [2,3-13C]succinate and [1,4-13C]succinate. III. Biosynthetic pathways.

The biosynthesis in vivo of a number of amino acids, sugars, and purines in Paracoccus denitrificans grown on either [2,3-13C]succinate or [1,4-13C]succinate was investigated by using gas chromatography-mass spectrometry. The distribution of label in the TCA-cycle-related amino acids indicated that carbon intermediates of energy metabolism were utilized as precursors for the biosynthesis of these amino acids in vivo. The biosynthesis of glycine, serine, phenylalanine and glycerol from labelled succinate in vivo were consistent with phosphoenol pyruvate as an intermediate. A mechanism for the formation of C4, C5 and C6 sugars without the use of fructose-1,6-bisphosphate aldolase (which has not been detected in P. denitrificans) is proposed. The 13C-enrichments of ribose in the bacterium indicate that there are at least three routes of ribose biosynthesis operating during growth on labelled succinate. The probability distribution of labelled purine molecules was successfully predicted for adenine, guanine and adenosine, thus confirming their generally accepted route of biosynthesis in vivo.

Conversion of melphalan to 4-(glutathionyl)phenylalanine. A novel mechanism for conjugation by glutathione-S-transferases.

One of the conjugates of melphalan, characterized following incubation with glutathione (GSH) and immobilized microsomal glutathione-S-transferases, has been identified as 4-(glutathionyl)-phenylalanine. This conjugate is formed by displacement of the mustard moiety. The structure was confirmed by reaction of the corresponding 4-halophenylalanines with GSH as well as by TLC, HPLC, and FAB mass spectrometry. Evidence is presented here to support the hypothesis that this novel reaction occurs via a cyclic aziridinium ion. To test this proposed mechanism, N,N-dimethyl-p-toluidine and its corresponding quaternary ammonium iodide salt were incubated with GSH in the presence of immobilized glutathione-S-transferases at 37 degrees C for 1 hr at pH 7.4. The tertiary amine did not react, whereas the quaternary compound produced 4-(glutathionyl)toluene. The effect of ring substituent requirements for the reaction was evaluated. The formation of GSH adducts of alkylating agents may be a factor in the development of resistance to these drugs.

Chloroplasts of higher plants synthesize L-phenylalanine via L-arogenate.

The specific enzymological route of L-phenylalanine biosynthesis has not been established in any higher plant system. The possible pathway routes that have been identified in microorganisms utilize either phenylpyruvate or L-arogenate as a unique intermediate. We now report the presence of arogenate dehydratase (which converts L-arogenate to L-phenylalanine) in cultured-cell populations of Nicotiana silvestris. Prephenate dehydratase (which converts prephenate to phenylpyruvate) was not detected. Arogenate dehydratase was also found in washed spinach chloroplasts, and these data add to emerging evidence in support of the existence in the plastidial compartment of a complete assembly of enzymes comprising aromatic amino acid biosynthesis. Arogenate dehydratase from tobacco and spinach were both specific for L-arogenate, inhibited by L-phenylalanine, and activated by L-tyrosine. Apparent Km values for L-arogenate (0.3 X 10(-3) M), pH optima (pH 8.5-9.5), and temperature optima for catalysis (32-34 degrees C) were also similar.

Chymotrypsin modified with polyethylene glycol catalyzes peptide synthesis reaction in benzene.

Chymotrypsin was modified in the zymogen form with 2,4-bis(O-methoxypolyethylene glycol)-6-chloro-s-triazine (activated PEG2), followed by activation with trypsin. The modified enzyme was soluble in benzene and retained its enzymic activity. Acid-amide bond formation by the modified enzyme proceeded efficiently in benzene: N-benzoyltyrosine butylamide was made from N-benzoyl-L-tyrosine ethyl ester and n-butylamine, and benzoyltyrosine(oligo)phenylalanine ethyl esters were formed from N-benzoyl-L-tyrosine ethyl ester and L-phenylalanine ethyl ester.

Protein synthesis in cell-free extracts of Coxiella burnetti.

Some aspects of protein biosynthesis were investigated in extracts of the obligate intracellular bacterium Coxiella burnetti. Sucrose gradient analysis revealed small quantities of 30S and 50S ribosomal subunits, few 70S ribosomes and no polysomes. Functional endogenous mRNA was not detected. In translation of exogenously added poly(U), extracts required Mg2+ (17 mM) and NH4+ (60 mM) for optimal polyphenylalanine synthesis; the optimum MG2+ requirement differed from that of Escherichia coli. The translation of coliphage Q beta RNA by C. burnetti extracts required Mg2+ (13 mM), NH4+ (60 mM) and an energy source for polypeptide synthesis, and was sensitive to chloramphenicol but not to cycloheximide. Under optimal conditions, the translation of Q beta RNA proceeded at a rate and to an extent equal to that obtained in a conventional E. coli system. Electrophoretic analysis of translation products made during incubation of C. burnetti extracts with polycistronic Q beta RNA revealed a major product with a molecular weight of about 14 000; this product co-electrophoresed with the coat protein extracted from Q beta phage propagated in E. coli. The results suggested that the extracellular form of the rickettsia-like organism, C. burnetti, possessed the full array of components necessary for the initiation, elongation and termination of polypeptides.

Resistance of the peptidyltransferase centre of rabbit ribosomes to attack by nucleases and proteinases.

Larger ribosomal subparticles (L-subparticles) of rabbit ribosomes were treated with either ribonucleases (I or T1) or proteinases (trypsin or chymotrypsin), and their capacity to function in poly(U)-directed polyphenylalanine synthesis and in the puromycin reaction was investigated. The effects of pretreatment of L-subparticles on the reconstruction of active subparticles from core-particles derived by treatment with 2.75 M-NH4Cl/69 mM-MgCl2 and split-protein fractions were also examined. The protein moiety of proteinase-treated L-subparticles was analysed by one-dimensional sodium dodecyl sulphate/polyacrylamide- and two-dimensional polyacrylamide-gel electrophoresis. The introduction of 16--100 scissions in the RNA moiety had no effect on the activity of the L-subparticles in polyphenylalanine synthesis, and there was no effect on the stability of L-subparticles to high-salt shock treatment and a marginal effect on the reconstruction of L-subparticles from high-salt-shock core-particles and split-protein fractions. In contrast, L-subparticles treated with low amounts of trypsin (0.56 ng of trypsin/microgram of L-subparticle) were inactive in polyphenylalanine synthesis, and their capacity to function in partial-reconstruction experiments was diminished. Activity in the puromycin reaction was increased by 70% as a result of trypsin treatment (280 ng of trypsin/microgram of L-subparticle). At least two of the acidic proteins implicated in the translocation function were not affected by trypsin treatment. Trypsin-treated L-subparticles had lost their capacity to bind the smaller ribosomal subparticle (S-subparticle). The protein(s) needed for S-subparticle binding were shown to be present in high-salt-shock cores. At least six proteins associated with the core-particles were attack during trypsin treatment of L-subparticles. An examination of L-subparticles isolated from trypsin-treated polyribosomes showed that the amount of trypsin necessary to decrease the activity of the subparticle by 50% was about twice that needed in the treatment of L-subparticles alone. The largest protein of rabbit L-subparticles (approx. 51 000 daltons) was cleaved in a stepwise fashion by trypsin to fragments of approx. 40 000 daltons. This protein was also cleaved by chymotrypsin.