Nature versus design: the conformational propensities of D-amino acids and the importance of side chain chirality

Towse, Clare-Louise, Hopping, G.G., Vulovic, I.M., Daggett, V.

2014 September 1918

No / D-amino acids are useful building blocks for de novo peptide design and they play a role in aging-related diseases associated with gradual protein racemization. For amino acids with achiral side chains, one should be able to presume that the conformational propensities of L- and D-amino acids are a reflection of one another due to the straightforward geometric inversion at the Cα atom. However, this presumption does not account for the directionality of the backbone dipole and the inverted propensities have never been definitively confirmed in this context. Furthermore, there is little known of how alternative side chain chirality affects the backbone conformations of isoleucine and threonine. Using a GGXGG host-guest pentapeptide system, we have completed exhaustive sampling of the conformational propensities of the D-amino acids, including D-allo-isoleucine and D-allo-threonine, using atomistic molecular dynamics simulations. Comparison of these simulations with the same systems hosting the cognate L-amino acids verifies that the intrinsic backbone conformational propensities of the D-amino acids are the inverse of their cognate L-enantiomers. Where amino acids have a chiral center in their side chain (Thr, Ile) the β-configuration affects the backbone sampling, which in turn can confer different biological properties. / NIH

MD simulation

Conformational sampling

D-amino acids

Epimerisation

Racemisation

Lysine Catabolism and In Vivo Substrate Specificity of D-Amino Acid Dehydrogenases in Pseudomonas Aeruginosa PAO1

Indurthi, Sai Madhuri

15 December 2016

Among multiple interconnected pathways for L-Lysine catabolism in pseudomonads, it has been reported that Pseudomonas aeruginosa PAO1 employs the decarboxylase and the transaminase pathways. However, knowledge of several genes involved in operation and regulation of these pathways was still missing. Transcriptome analyses coupled with promoter activity measurements and growth phenotype analyses led us to identify new members in L-Lys and D-Lys catabolism and regulation, including gcdR-gcdHG for glutarate utilization, dpkA, amaR-amaAB and PA2035 for D-Lys catabolism, lysR-lysXE for putative L-Lys efflux and lysP for putative L-Lys uptake. The amaAB operon is induced by L-Lys, D-Lys and pipecolate supporting the convergence of Lys catabolic pathways to pipecolate. Growth on pipecolate was retarded in the gcdG and gcdH mutants, suggesting the importance of glutarate in pipecolate and 2-aminoadipate utilization. Furthermore, this study indicated links in control of interconnected networks of lysine and arginine catabolism in P. aeruginosa. Effect of D-amino acids and the genes involved in their metabolism are of great interest in both bacteria and mammals. D-Arg utilization in PAO1 requires the coupled dehydrogenases DauB and DauA. In this study, DauB was found to use only L-Arg as its substrate unlike its partner dehydrogenase DauA with wide substrate specificity. However, evidence from this study and previous studies suggest that the coupled enzymes DauB and DauA are unique for D-Arg catabolism. The three D-amino acid dehydrogenases DguA, DadA and DauA were found to have somewhat limited in vivo substrate specificity compared to that found in vitro tested using purified enzymes. Many studies showed that D-amino acids are toxic to bacteria. The ΔdguA, ΔdadA and ΔdauA triple mutant had two-fold lower minimum inhibition concentration of carbenicillin and tetracycline compared to wild-type PAO1. Both in the wild-type PAO1 and the triple mutant, synergy was observed between gentamicin or tetracycline (at concentrations below the MIC) and D-amino acids resulting in growth inhibition or reduction, respectively. However, no special synergistic or antagonistic effects were observed specifically in the ΔdguA, ΔdadA and ΔdauA triple mutant as compared to the wild-type PAO1 when D-amino acids were given in combination with antibiotics.

Pseudomonas

Lysine

Catabolism

Uptake

Regulation

Dehydrogenase

D-amino acids

Antibiotics

Synergy

The Impact of D-amino acids on Formation and Integrity of Biofilm – Effect of Growth Condition and Bacteria Type

Li, Xuening

16 September 2013

Biofouling is a major issue in applying nanofiltration and reverse osmosis technologies for wastewater treatment. Biofilm formed on the surface of membranes will severely decline the flux and cause energy waste. In this study, a novel biofouling control method that applies D-amino acids to inhibit biofilm formation was investigated. The D-amino acids previously reported to inhibit biofilm formation and disrupt existing biofilm – D-tyrosine and the mixture of D-tyrosine, D-tryptophan, D-leucine and D-methionine were tested. Pseudomonas aeruginosa and Bacillus subtilis were used as model Gram-negative and Gram-positive bacteria, respectively. D-amino acids have little effect and some effect on inhibition of biofilm formation and disruption of exiting biofilm to Pseudomonas aeruginosa, but have good effect to Bacillus subtilis. A commonly used microtiter plate assay for quantitative biofilm measurement was systematically evaluated and optimized for screening biofilm control agents. The effect of D-tyrosine on inhibition of organic fouling and P. aeruginosa biofouling on NF90 membrane surface in bench scale dead end filtration experiment was examined, which shows that D-tyrosine can effectively inhibit organic fouling and P. aeruginosa biofouling on NF90 membrane surface.

Anti-biofouling

NF/RO membrane

D-amino acids

microtiter plate assay

Investigation into the Effects of PEGylation on the Thermodynamic Stability of the WW Domain

Matthews, Sam S

01 December 2013

The covalent attachment of poly(ethylene glycol) (PEG) to a protein surface (known as PEGylation), has been demonstrated to increase the serum half-life of therapeutic proteins by reducing kidney clearance and immunogenicity and by protecting against proteolysis. Theses beneficial effects could be further enhanced if PEGylation consistently increased protein conformational stability (i.e. the difference in free energy between the folded and unfolded states). However, the effects of PEGylation on protein conformational stability are unpredictable; PEGylation has been reported to increase, decrease, or have no effect on the conformational stability of medicinal proteins.This thesis details the results of two studies aimed at discovering the structural determinants which influence the thermodynamic impact of PEGylation on the WW domain, a small model protein. Chapter 1 is a brief introduction to protein therapeutics and protein PEGylation. Chapter 2 describes a study which demonstrates that the thermodynamic impact of PEGylation is strongly dependent on the site to which PEG is conjugated. The studies described in Chapter 3 elaborate on this site dependence, and demonstrate that PEG stabilizes the WW domain through interactions with the surface of the folded peptide, and that two factors – the orientation of the PEG chain (relative to the protein surface) and the identity of nearby side chains – play a critical role in determining the thermodynamic impact of PEGylation.

PEGylation

Therapeutic Proteins

Thermodynamic Stability

Circular Dichroism

beta-sheet

D-Amino Acids

Biochemistry

Chemistry

UNVEILING NOVEL ASPECTS OF D-AMINO ACID METABOLISM IN THE MODEL BACTERIUM PSEUDOMONAS PUTIDA KT2440

Radkov, Atanas D.

01 January 2015

D-amino acids (D-AAs) are the α-carbon enantiomers of L-amino acids (L- AAs), the building blocks of proteins in known organisms. It was largely believed that D-AAs are unnatural and must be toxic to most organisms, as they would compete with the L-counterparts for protein synthesis. Recently, new methods have been developed that allow scientists to chromatographically separate the two AA stereoisomers. Since that time, it has been discovered that D-AAs are vital molecules and they have been detected in many organisms. The work of this dissertation focuses on their place in bacterial metabolism. This specific area was selected due to the abundance of D-AAs in bacteria-rich environments and the knowledge of their part in several processes, such as peptidoglycan synthesis, biofilm disassembly, and sporulation. We focused on the bacterium Pseudomonas putida KT2440 which inhabits the densely populated plant rhizosphere. Due to its versatility and cosmopolitan character, this bacterium has provided an excellent system to study D-AA metabolism. In the first chapter, we have developed a new approach to identify specific genes encoding enzymes acting on D-AAs, collectively known as amino acid racemases. Using this novel method, we identified three amino acid racemases encoded by the genome of P. putida KT2440. All of the enzymes were subsequently cloned and purified to homogeneity, followed by a complete biochemical characterization. The aim of the second chapter was to understand the specific role of the peculiar broad-spectrum amino acid racemase Alr identified in chapter one. After constructing a markerless deletion of the cognate gene, we conducted a variety of phenotypic assays that led to a model for a novel catabolic pathway that involves D-ornithine as an intermediate. The work in chapter three identifies for the first time numerous rhizosphere-dwelling bacteria capable of catabolizing D-AAs. Overall, the work in this dissertation contributes a novel understanding of D-AA catabolism in bacteria and aims to stimulate future efforts in this research area.

D-amino acids

rhizosphere

Pseudomonas putida KT2440

catabolism

Bacteriology

Microbial Physiology

Plant Biology

Microbiologically Influenced Corrosion (MIC) Mechanisms and Mitigation

Xu, Dake

26 September 2013

No description available.

Chemical Engineering

Microbiologically Influenced Corrosion

Sulfate reducing bacteria

Nitrate reducing bacteria

extracellular electron transfer

bioenergentics

D-amino acids

biocide enhancer

D-Tryptophan as a Biocide Enhancer for Desulfovibrio vulgaris Biofilm Mitigation andBiocorrosion of Carbon Steel by Nitrate-Reducing Pseudomonas aeruginosa

Lindenberger, Amy L.

January 2014

No description available.

Chemical Engineering

microbiologically influenced corrosion

biocorrosion

sulfate-reducing bacteria

Desulfovibrio vulgaris

nitrate-reducing bacteria

Pseudomonas aeruginosa

biocide enhancer

D-amino acids

D-tryptophan

carbon steel

Mechanisms of Corrosion Caused by Anaerobic Biofilms and Its Mitigation Using a Biocide Enhanced by D-Amino Acids

Cai, Weizhen

January 2017

No description available.

Biomedical Engineering

Chemical Engineering

microbiologically influenced corrosion

biocorrosion

sulfate-reducing bacteria

Desulfovibrio vulgaris

nitrate-reducing bacteria

Pseudomonas aeruginosa

biocide enhancer

D-amino acids

carbon steel

stainless steel

H2S

Synthesis of antimicrobial peptides derived from BP100 and BPC194

Güell Costa, Imma

27 January 2012

In the present PhD thesis we studied the solid-phase peptide synthesis of antimicrobial peptides derived from the lead peptides BP100 and BPC194. First, peptides derived from BP100 containing D-amino acids at different positions of the sequences were prepared. Moreover, peptidotriazoles derived from BP100 were also synthesized containing the triazole ring at the side-chain of different amino acids. Then, we proceeded to perform studies for the synthesis of multivalent peptides derived from BPC194. To achieve this objective, the synthesis of cyclic peptides containig a triazole ring at amino acids side-chain with different elongations was carried out. Finally, we prepared various carbopeptides containing 2 and 4 units of BP100 and/or its derivatives. The evaluation of the biological activity allowed the identification of active sequences against the economically important phytopathogenic bacteria and fungi and not toxic against eukaryotic cells. / En aquesta tesi doctoral es va estudiar la preparació en fase sòlida de pèptids antimicrobians derivats dels pèptids lead BP100 i BPC194. En primer lloc, es varen preparar derivats del pèptid lineal BP100 incorporant D aminoàcids en diferents posicions de la seqüència. A més, també es varen sintetitzar derivats d'aquest pèptid lead incorporant un anell de triazole a la cadena lateral de diferents aminoàcids. Posteriorment, es va procedir a l'estudi de la síntesi dd pèptids multivalents derivats de BPC194. Per aconseguir aquest objectiu es va portar a terme la síntesi de pèptids cíclics incorporant un anell de triazole a la cadena lateral d’aminoàcids amb diferents allargades de cadena. Finalment, va procedir a la preparació de carbopèptids contenint 2 i 4 unitats de BP100 i/o derivats. L’avaluació de l’activitat biològica dels pèptids sintetitzats va permetre idenficar seqüències actives enfront de bacteris fitopatògens i fongs i poc tòxiques enfront cèl•lules eucariotes.

Carbopeptides

Carbopèptids

Carbopéptidos

Antimicrobial peptides

Pèptids antimicrobials

Péptidos antimicrobianos

Cyclic peptides

Pèptids cíclics

Péptidos cíclicos

D-amino acids

D aminoàcids

D aminoácidos

Solid-phase

Fase sòlida

Fase sólida

547

Racemases in Salmonella : Insights into the Dexterity of the Pathogen

Iyer, Namrata

January 2014

Chapter -I Introduction Salmonella is a pathogen well-known for its ability to infect a wide variety of hosts and causes disease ranging from mild gastroenteritis to typhoid fever. During infection, it is exposed to a myriad of conditions; from the aquatic environment, the gut lumen to the phagolysosome. The success of Salmonella as a pathogen lies in its ability to sense each of these environments and adapt itself for survival and proliferation accordingly. This is done mainly via the action of specific two-component systems (TCSs) which sense cues specific to each of these niches and trigger the appropriate transcriptional reprogramming. This reprogramming is best studied for the genes directly known to be involved in virulence. In the case of Salmonella, most of these genes are a part of specific clusters, acquired through horizontal gene transfer, known as Salmonella Pathogenicity Islands (SPIs). Of the various SPIs, the two most important are SPI-1 and SPI-2. SPI-1 is classically involved in orchestrating bacterial invasion of non-phagocytic cells in the gut, allowing the pathogen to invade the host. Furthermore, its role is well characterized in the classic inflammation associated with gastroenteritis. On the other hand, SPI-2 is specialized for survival within the harsh intracellular environment of host cells such as macrophages and epithelial cells. Other important virulence determinants include motility, chemotaxis as well as adhesins. The transcription of these virulence genes is under tight regulation and responsive to environmental conditions. Many small molecules such as short chain fatty acids, pp(p)Gpp, bile and acyl homoserine lactones among others are known to be potent regulators of virulence in Salmonella. Furthermore, the metabolic products of the normal flora in the gut also affect its virulence. Thus the metabolic status, of both the host as well as the pathogen, plays an important role in determining the outcome of the infection. Many metabolic enzymes and their products are now known to directly or indirectly affect virulence gene expression. In this study, we explore one such class of metabolic enzymes viz amino acid racemases. They catalyze the chiral conversion of L-amino acids to D-amino acids and vice versa. We have studied the biochemical properties of two such non-canonical racemases as well as their role in bacterial survival and pathogenesis. Chapter-II Identification and characterization of putative aspartate racemases in Salmonella Amino acid racemases, such as alanine and glutamate racemases, are ubiquitously found in all bacteria and they play an essential role in cell wall biosynthesis. Recently it has been found, that bacteria possess other amino acid racemases which produce non-canonical D-amino acids. These D-amino acids, upon secretion, further orchestrate various phenotypes such as cell wall remodeling and biofilm dispersal. In this study, we have explored the ability of Salmonella to produce such non-canonical D-amino acids. The genome of S. Typhimurium possesses genes encoding two putative aspartate racemases; ygeA and aspR. These genes were maximally expressed in mid-log phase of bacterial growth and their corresponding proteins ar localized in the outer membrane of the bacterium. The biochemical characterization of the proteins YgeA and AspR revealed that only the latter is catalytically active under in vitro conditions. AspR could catalyze the conversion of L-Aspartate to D-Aspartate and vice versa, however was unable to use any other amino acid as its substrate. With atleast one of the racemases showing catalytic activity, the profiling of the secreted D-amino acids in Salmonella conditioned medium was undertaken using LC-MS. It was observed that the bacterium actively secreted specific D-amino acids such as D-Ala and D-Met into the culture medium in a growth-phase dependent manner. Furthermore, analysis of the secreted D-amino acid profile of the strains lacking either one or both the racemases revealed that atleast a subset of the secreted D-amino acids were dependent on the activity of YgeA and AspR. Thus, D-amino acids secreted by S. Typhimurium might represent a novel class of signaling molecules. Chapter – III Role of aspartate racemases in growth and survival of S. Typhimurium In order to understand the role of ygeA and aspR in vivo, we created knockouts of these genes (both single as well as double knockout) in S. Typhimurium using λ Red recombinase strategy. These knockouts were then assessed for their growth and morphology. The aspartate racemase knockouts behave similar to the wild type during growth in LB as well as M9 minimal medium. While their gross morphology remained the same as the wild type, the size distribution of the racemase knockouts was slightly different in the stationary phase. Unlike the wild type bacteria, the mutants did not exhibit the characteristic reduction in cell size upon entry into stationary phase. In addition, the survival of the mutants in the presence of cell wall damaging agents such as bile and Triton-X 100 was compromised as compared to the wild type. This can be ascribed to changes in the cell wall of the bacterium, wherein the mutants accumulated peptidoglycan in the stationary phase of growth. This suggests that aspartate racemases might have an effect on cell wall biosynthesis in Salmonella in the stationary phase. Another important strategy employed by bacteria to survive in stress conditions is biofilm formation. It was seen that the mutants were compromised in their ability to form a biofilm at the liquid-air interface in vitro. This defect is due to a transcriptional downregulation of the genes required for biofilm formation. These results demonstrate that, contrary to the established inhibitory effects of D-amino acids on biofilms of various bacteria, the aspartate racemases appear to act as positive regulators of biofilm formation in Salmonella. Chapter – IV Involvement of aspartate racemases in the regulation of Salmonella pathogenesis Salmonella’s success as a pathogen can be broadly assessed by its ability to invade and replicate within two major cell types: epithelial cells and macrophage-like cells. We have studied the fate of the aspartate racemase knockout strains in both these cell types. While the mutants replicate as well as the wild type in macrophage cell lines, their ability to invade epithelial cell lines is highly compromised. This defect can be ascribed to the downregulation of the Salmonella Pathogenicity Island-1 (SPI-1) in the racemase knockouts at the transcriptional level. One of the major pathways that regulate SPI-1 activation is the flagellar pathway. It was observed that in addition to SPI-1, the motility of the racemase mutants was also highly compromised. The mutants did not possess any flagella and showed a high transcriptional downregulation of all the three classes of flagellar genes. Transcriptome analysis revealed a global reprogramming in the aspartate racemase mutants, resulting in the differential regulation of motility, adhesion, amino acid transport, cell wall biosynthesis and other pathways. Of the genes upregulated in the knockouts, FimZ is known for its negative effect on motility and might be responsible for the observed downregulation of the flagellar regulon. This suggests that ygeA and aspR might be repressors of fimbrial gene expression. In totality, the racemases affected the pathogenesis of Salmonella, where the double knockout was severely compromised in the colitis model of infection. Overall the study is the first to identify secretion of non-canonical D-amino acids by Salmonella and suggests that YgeA and AspR might be the source of the same. This is supported in part by in vitro studies with the purified proteins. Studies in vivo further highlight the possible substrates that might be utilized by these enzymes. Physiologically, the aspartate racemases appear to regulate cell wall remodeling and biofilm formation. In contrast to the established literature, aspartate racemases (and their possible D-amino acid products) seem to be essential for formation of biofilms and regulate this phenotype at the transcriptional level. Furthermore, our studies put forth aspartate racemases as novel positive regulators of Flagella and SPI-1, affecting the success of Salmonella in the colitis model of infection in mice. Transcriptome analysis hints at the pleiotropic effects of aspartate racemases in Salmonella, bringing forth hitherto unexplored roles for this class of enzymes in the biology of this pathogen.

Salmonella Typhimurium

Salmonella Pathogenicity Islands (SPIs)

Amino Acid Racemases

Salmonella Pathogenesis

D-Amino Acids

Salmonella Racemases

Aspartate Racemases

Bacterial Virulence

Salmonella Virulence

Putative Aspartate Racemases

Salmonella Infection

S. Typhimurium

Mirobiology