Further evidence supporting the role of GTDC1 in glycine metabolism and neurodevelopmental disorders.

Copy number variants (CNVs) represent the genetic cause of about 15-20% of neurodevelopmental disorders (NDDs). We identified a ~67 kb de novo intragenic deletion on chromosome 2q22.3 in a female individual showing a developmental encephalopathy characterised by epilepsy, severe intellectual disability, speech delay, microcephaly, and thin corpus callosum with facial dysmorphisms. The microdeletion involved exons 5-6 of GTDC1, encoding a putative glycosyltransferase, whose expression is particularly enriched in the nervous system. In a previous study, a balanced de novo translocation encompassing GTDC1 was reported in a male child with global developmental delay and delayed speech and language development. Based on these premises, we explored the transcriptomic profile of our proband to evaluate the functional consequences of the novel GTDC1 de novo intragenic deletion in relation to the observed neurodevelopmental phenotype. RNA-seq on the proband's lymphoblastoid cell line (LCL) showed expression changes of glycine/serine and cytokine/chemokine signalling pathways, which are related to neurodevelopment and epileptogenesis. Subsequent analysis by ELISA (enzyme-linked immunosorbent assay) and HPLC (high-performance liquid chromatography) revealed increased levels of glycine in the proband's LCL and serum compared to matched controls. Given that an increased level of glycine has been observed in the plasma samples of individuals with Rett syndrome, a condition sharing epilepsy, microcephaly, and intellectual disability with our proband, we proposed that the GTDC1 downregulation is implicated in neurodevelopmental impairment by altering glycine metabolism. Furthermore, our findings expanded the phenotypic spectrum of the novel GTDC1-related condition, including microcephaly and epilepsy among relevant clinical features.

Effect of glycosylation on the affinity of the MTB protein Ag85B for specific antibodies: towards the design of a dual-acting vaccine against tuberculosis.

BACKGROUND: To create a dual-acting vaccine that can fight against tuberculosis, we combined antigenic arabino-mannan analogues with the Ag85B protein. To start the process, we studied the impact of modifying different parts of the Ag85B protein on its ability to be recognized by antibodies. RESULTS: Through our research, we discovered that three modified versions of the protein, rAg85B-K30R, rAg85B-K282R, and rAg85B-K30R/K282R, retained their antibody reactivity in healthy individuals and those with tuberculosis. To further test the specificity of the sugar AraMan for AraMan antibodies, we used Human Serum Albumin glycosylated with AraMan-IME and Ara3Man-IME. Our findings showed that this specific sugar was fully and specifically modified. Bio-panning experiments revealed that patients with active tuberculosis exhibited a higher antibody response to Ara3Man, a sugar found in lipoarabinomannan (LAM), which is a major component of the mycobacterial cell wall. Bio-panning with anti-LAM plates could eliminate this increased response, suggesting that the enhanced Ara3Man response was primarily driven by antibodies targeting LAM. These findings highlight the importance of Ara3Man as an immunodominant epitope in LAM and support its role in eliciting protective immunity against tuberculosis. Further studies evaluated the effects of glycosylation on the antibody affinity of recombinant Ag85B and its variants. The results indicated that rAg85B-K30R/K282R, when conjugated with Ara3Man-IME, demonstrated enhanced antibody recognition compared to unconjugated or non-glycosylated versions. CONCLUSIONS: Coupling Ara3Man to rAg85B-K30R/K282R could lead to the development of effective dual-acting vaccines against tuberculosis, stimulating protective antibodies against both AraMan and Ag85B, two key tuberculosis antigens.

Glycovaccine Design: Optimization of Model and Antitubercular Carrier Glycosylation via Disuccinimidyl Homobifunctional Linker.

Conjugation via disuccinimidyl homobifunctional linkers is reported in the literature as a convenient approach for the synthesis of glycoconjugate vaccines. However, the high tendency for hydrolysis of disuccinimidyl linkers hampers their extensive purification, which unavoidably results in side-reactions and non-pure glycoconjugates. In this paper, conjugation of 3-aminopropyl saccharides via disuccinimidyl glutarate (DSG) was exploited for the synthesis of glycoconjugates. A model protein, ribonuclease A (RNase A), was first considered to set up the conjugation strategy with mono- to tri- mannose saccharides. Through a detailed characterization of synthetized glycoconjugates, purification protocols and conjugation conditions have been revised and optimized with a dual aim: ensure high sugar-loading and avoid the presence of side reaction products. An alternative purification approach based on hydrophilic interaction liquid chromatography (HILIC) allowed the formation of glutaric acid conjugates to be avoided, and a design of experiment (DoE) approach led to optimal glycan loading. Once its suitability was proven, the developed conjugation strategy was applied to the chemical glycosylation of two recombinant antigens, native Ag85B and its variant Ag85B-dm, that are candidate carriers for the development of a novel antitubercular vaccine. Pure glycoconjugates (≥99.5%) were obtained. Altogether, the results suggest that, with an adequate protocol, conjugation via disuccinimidyl linkers can be a valuable approach to produce high sugar-loaded and well-defined glycovaccines.

The Role of D-Amino Acids in Alzheimer's Disease.

Alzheimer's disease (AD), the main cause of dementia worldwide, is characterized by a complex and multifactorial etiology. In large part, excitatory neurotransmission in the central nervous system is mediated by glutamate and its receptors are involved in synaptic plasticity. The N-methyl-D-aspartate (NMDA) receptors, which require the agonist glutamate and a coagonist such as glycine or the D-enantiomer of serine for activation, play a main role here. A second D-amino acid, D-aspartate, acts as agonist of NMDA receptors. D-amino acids, present in low amounts in nature and long considered to be of bacterial origin, have distinctive functions in mammals. In recent years, alterations in physiological levels of various D-amino acids have been linked to various pathological states, ranging from chronic kidney disease to neurological disorders. Actually, the level of NMDA receptor signaling must be balanced to promote neuronal survival and prevent neurodegeneration: this signaling in AD is affected mainly by glutamate availability and modulation of the receptor's functions. Here, we report the experimental findings linking D-serine and D-aspartate, through NMDA receptor modulation, to AD and cognitive functions. Interestingly, AD progression has been also associated with the enzymes related to D-amino acid metabolism as well as with glucose and serine metabolism. Furthermore, the D-serine and D-/total serine ratio in serum have been recently proposed as biomarkers of AD progression. A greater understanding of the role of D-amino acids in excitotoxicity related to the pathogenesis of AD will facilitate novel therapeutic treatments to cure the disease and improve life expectancy.

Serum D-serine levels are altered in early phases of Alzheimer's disease: towards a precocious biomarker.

D-Serine acts as a co-agonist of N-methyl-D-aspartate receptors (NMDAR) which appear overactivated in AD, while D-aspartate is a modulatory molecule acting on NMDAR as a second agonist. The aim of this work is to clarify whether the levels of these D-amino acids in serum are deregulated in AD, with the final goal to identify novel and precocious biomarkers in AD. Serum levels of L- and D-enantiomers of serine and aspartate were determined by HPLC using a pre-column derivatization procedure and a selective enzymatic degradation. Experimental data obtained from age-matched healthy subjects (HS) and AD patients were statistically evaluated by considering age, gender, and disease progression, and compared. Minor changes were apparent in the serum L- and D-aspartate levels in AD patients compared to HS. A positive correlation for the D-serine level and age was apparent in the AD cohort. Notably, the serum D-serine level and the D-/total serine ratio significantly increased with the progression of the disease. Gender seems to have a minor effect on the levels of all analytes tested. This work proposes that the serum D-serine level and D-/total serine ratio values as novel and valuable biomarkers for the progression of AD: the latter parameter allows to discriminate CDR 2 and CDR 1 patients from healthy (CDR 0) individuals.

Epitope and affinity determination of recombinant Mycobacterium tuberculosis Ag85B antigen towards anti-Ag85 antibodies using proteolytic affinity-mass spectrometry and biosensor analysis.

Tuberculosis (TB) is the first cause of death from infectious diseases worldwide. Only a single anti-TB vaccine is currently available for clinical use, but its efficacy is not achieved with certainty. The aim of this work is to provide a basis for the rational design of a neo-glycoconjugate vaccine against TB. Structural characterization of recombinant antigenic proteins from Mycobacterium tuberculosis (MTB) Ag85B (rAg85B, variants, and semi-synthetic glycoconjugates) was initially carried out. Identification of antibody epitope analyses by proteolytic affinity-mass spectrometry and surface plasmon resonance (SPR) biosensor analyses were performed in order to qualitatively identify and quantitatively characterize interaction structures of the antigens with antibodies from different sources. A commercial monoclonal antibody and polyclonal antibodies from different sources (patients with active TB, vaccinated individuals, and a healthy control) were employed to analyze antigen-antibody interactions. These combined approaches provided the identification of different assembled epitope regions on the recombinant MTB antigens, their affinity binding constants in the interactions with specific antibodies, and revealed the importance of protection from excessive glycosylation. The identified epitope peptides should constitute a suitable basis for the design of new specific target vaccines. Graphical abstract ᅟ.

Enterokinase monolithic bioreactor as an efficient tool for biopharmaceuticals preparation: on-line cleavage of fusion proteins and analytical characterization of released products.

One of the most popular enzymes used for the in vitro cleavage of fusion proteins is enterokinase (EK, E.C. 3.4.21.9). EK cleaves with high specificity after the sequence Asp4-Lys (DDDDK), which allows the fusion protein to preserve its native amino acid terminus without any additional unwanted cleavage residue from the recognition sequence. However, the complete removal of EK after protein cleavage is a critical step to ensure protein identity and stability. As enzyme immobilization increases stability and reusability of the biocatalyst while reducing operating costs and sample contamination, in this work we report the covalent immobilization of recombinant EK (rEK) on monolithic chromatographic supports with different binding chemistries for the development of a rEK-chromatographic-bioreactor. An on-line assay for the determination of the activity of the immobilized rEK was set up using a synthetic substrate (Gly-Asp4-Lys-ß-naphthylamide, GD4K-NA). The assay was used to study the improvement of the operational conditions (temperature and flow rate) on hydrolytic activity of the bioreactor. The immobilization yields, as well as the cleavage activity of immobilized rEK on GD4K-NA, were highly satisfactory when the immobilized enzyme reactor was used in recirculation. The ability of the immobilized rEK to cleave fusion proteins was tested by recirculation of thioredoxin (Trx)-TB10.4 and Trx-Ag85B His-tagged proteins yielding the mature antigens TB10.4 and Ag85B, to be used in the preparation of potential novel glycovaccines against tuberculosis. The prepared rEK-based immobilized enzyme reactors proved to efficiently cleave the considered fusion proteins even if the cleavage specificity at the canonical site was not fully achieved. The immobilized rEK showed very good stability and reusability.

D-Amino Acid Oxidase-pLG72 Interaction and D-Serine Modulation.

pLG72 is a small, primate-specific protein of 153 amino acids. It is the product of the G72 gene, expressed in testis, spinal cord, and brain. The presence of G72 transcript and pLG72 has recurrently been called into question, however G72 mRNA and pLG72 protein levels were higher in blood and brain of patients with schizophrenia than in healthy controls. On the one hand, the SNP rs2391191 corresponding to the R30K substitution in pLG72 was genetically linked to schizophrenia, reduced thickness of the brain cortex in schizophrenia-affected individuals, and altered memory function. Various lines of evidence indicated that pLG72 is a mitochondrial protein, specifically an extrinsic protein bound on the outer membrane. Over the years, pLG72 was proposed to be involved in different functions: (a) overexpression induces mitochondria fragmentation, increasing the numbers of shorter and more mobile ones which could be delivered faster to regions of intense growth and facilitating the dendritic complexity; (b) it might induce oxidative stress by interacting with methionine-R-sulfoxide reductase B2; and (c) it binds and modulates the activity of FMN-containing oxidoreductase of the respiratory complex I. The main role of this protein, however, is related to its binding to the human flavoenzyme D-amino acid oxidase (hDAAO), i.e., the main catabolic enzyme for D-enantiomer of serine. This D-amino acid is a main endogenous coagonist of the N-methyl-D-aspartate type glutamate receptor (NMDAR) involved in main functions such as synaptic plasticity, learning, memory, and excitotoxicity. For this work, we reviewed the recent literature concerning the hDAAO-pLG72 interaction, focusing on the molecular details of the interaction, the effect of hDAAO function and stability, and the cellular effects, especially on D-serine concentration. The main effects related to the pathological R30K substitution are also reported. We have highlighted the gaps in our knowledge of this human protein as well as the relevance of clarifying the molecular details of hDAAO-pLG72 interaction in order to design molecules to modulate hDAAO activity/stability and thus NMDAR function acting at the D-serine cellular level.

Rational design, preparation and characterization of recombinant Ag85B variants and their glycoconjugates with T-cell antigenic activity against Mycobacterium tuberculosis.

Tuberculosis is the deadliest infectious disease in the world. The variable efficacy of the current treatments highlights the need for more effective agents against this disease. In the past few years, we focused on the investigation of antigenic glycoconjugates starting from recombinant Ag85B (rAg85B), a potent protein antigen from Mycobacterium tuberculosis. In this paper, structural modifications were rationally designed in order to obtain a rAg85B variant protein able to maintain its immunogenicity after glycosylation. Lysine residues involved in the main T-epitope sequences (namely, K30 and K282) have been substituted with arginine to prevent their glycosylation by a lysine-specific reactive linker. The effectiveness of the mutation strategy and the detailed structure of resulting neo-glycoconjugates have been studied by intact mass spectrometry, followed by peptide and glycopeptide mapping. The effect of K30R and K282R mutations on the T-cell activity of rAg85B has also been investigated with a preliminary immunological evaluation performed by enzyme-linked immunospotting on the different variant proteins and their glycosylation products. After glycosylation, the two variant proteins with an arginine in position 30 completely retain the original T-cell activity, thus representing adequate antigenic carriers for the development of efficient glycoconjugate vaccines against tuberculosis.

Hydrophilic interaction liquid chromatography-mass spectrometry as a new tool for the characterization of intact semi-synthetic glycoproteins.

Improved methods for detailed characterization of complex glycoproteins are required in the growing sector of biopharmaceuticals. Hydrophilic interaction liquid chromatography (HILIC) coupled to high resolution (HR) time-of-flight mass spectrometric (TOF-MS) detection was examined for the characterization of intact neo-glycoproteins prepared by chemical conjugation of synthetic saccharides to the lysine residues of selected recombinant proteins. The separation performances of three different amide HILIC columns (TSKgel Amide-80, XBridge BEH and AdvanceBio Glycan Mapping) were tested. Water-acetonitrile gradients and volatile eluent additives have been explored. Addition of 0.05% (v/v) trifluoroacetic acid to the mobile phase appeared to be essential for achieving optimum resolution of intact glycoforms and minimal ion suppression effects. Gradient elution conditions were optimized for each protein on every column. HILIC stationary phases were evaluated for the analysis of highly heterogeneous semi-synthetic derivatives of the same protein (ribonuclease A), and in the enhanced characterization of TB10.4 and Ag85B glycoconjugates, selected antigens from Mycobacterium tuberculosis (MTB). HILIC-MS results indicated that the HILIC selectivity is predominantly governed by size of the conjugated glycans and number of glycans attached, providing efficient glycoform separation. Moreover, HILIC separation prior to HRMS detection allowed assignment of several product impurities. Additional top-down MS/MS experiments confirmed conjugation at the N-terminus of TB10.4 next to its lysine residue. Overall, the obtained results demonstrate that amide-stationary-phase based HILIC coupled to MS is highly useful for the characterization of intact neo-glycoproteins allowing assessment of the number, identity and relative abundance of glycoforms present in the semi-synthetic products.

Glycosylation of Recombinant Antigenic Proteins from Mycobacterium tuberculosis: In Silico Prediction of Protein Epitopes and Ex Vivo Biological Evaluation of New Semi-Synthetic Glycoconjugates.

Tuberculosis is still one of the most deadly infectious diseases worldwide, and the use of conjugated antigens, obtained by combining antigenic oligosaccharides, such as the lipoarabinomannane (LAM), with antigenic proteins from Mycobacterium tuberculosis (MTB), has been proposed as a new strategy for developing efficient vaccines. In this work, we investigated the effect of the chemical glycosylation on two recombinant MTB proteins produced in E. coli with an additional seven-amino acid tag (recombinant Ag85B and TB10.4). Different semi-synthetic glycoconjugated derivatives were prepared, starting from mannose and two disaccharide analogs. The glycans were activated at the anomeric position with a thiocyanomethyl group, as required for protein glycosylation by selective reaction with lysines. The glycosylation sites and the ex vivo evaluation of the immunogenic activity of the different neo-glycoproteins were investigated. Glycosylation does not modify the immunological activity of the TB10.4 protein. Similarly, Ag85B maintains its B-cell activity after glycosylation while showing a significant reduction in the T-cell response. The results were correlated with the putative B- and T-cell epitopes, predicted using a combination of in silico systems. In the recombinant TB10.4, the unique lysine is not included in any T-cell epitope. Lys30 of Ag85B, identified as the main glycosylation site, proved to be the most important site involved in the formation of T-cell epitopes, reasonably explaining why its glycosylation strongly influenced the T-cell activity. Furthermore, additional lysines included in different epitopes (Lys103, -123 and -282) are also glycosylated. In contrast, B-cell epitopic lysines of Ag85B were found to be poorly glycosylated and, thus, the antibody interaction of Ag85B was only marginally affected after coupling with mono- or disaccharides.

Assays of D-Amino Acid Oxidase Activity.

D-amino acid oxidase (DAAO) is a well-known flavoenzyme that catalyzes the oxidative FAD-dependent deamination of D-amino acids. As a result of the absolute stereoselectivity and broad substrate specificity, microbial DAAOs have been employed as industrial biocatalysts in the production of semi-synthetic cephalosporins and enantiomerically pure amino acids. Moreover, in mammals, DAAO is present in specific brain areas and degrades D-serine, an endogenous coagonist of the N-methyl-D-aspartate receptors (NMDARs). Dysregulation of D-serine metabolism due to an altered DAAO functionality is related to pathological NMDARs dysfunctions such as in amyotrophic lateral sclerosis and schizophrenia. In this protocol paper, we describe a variety of direct assays based on the determination of molecular oxygen consumption, reduction of alternative electron acceptors, or α-keto acid production, of coupled assays to detect the hydrogen peroxide or the ammonium production, and an indirect assay of the α-keto acid production based on a chemical derivatization. These analytical assays allow the determination of DAAO activity both on recombinant enzyme preparations, in cells, and in tissue samples.

Different recombinant forms of polyphenol oxidase A, a laccase from Marinomonas mediterranea.

Polyphenol oxidase from the marine bacterium Marinomonas mediterranea (MmPPOA) is a membrane-bound, blue, multi-copper laccase of 695 residues. It possesses peculiar properties that distinguish it from known laccases, such as a broad substrate specificity (common to tyrosinases) and a high redox potential. In order to push the biotechnological application of this laccase, the full-length enzyme was overexpressed in Escherichia coli cells with and without a C-terminal His-tag. The previous form, named rMmPPOA-695-His, was purified to homogeneity by HiTrap chelating chromatography following solubilization by 1% SDS in the lysis buffer with an overall yield of ≈1 mg/L fermentation broth and a specific activity of 1.34 U/mg protein on 2,6-dimethoxyphenol as substrate. A truncated enzyme form lacking 58 residues at the N-terminus encompassing the putative membrane binding region, namely rMmPPOA-637-His, was successfully expressed in E. coli as soluble protein and was purified by using the same procedure set-up as for the full-length enzyme. Elimination of the N-terminal sequence decreased the specific activity 15-fold (which was partially restored in the presence of 1 M NaCl) and altered the secondary and tertiary structures and the pH dependence of optimal stability. The recombinant rMmPPOA-695-His showed kinetic properties on catechol higher than for known laccases, a very high thermal stability, and a strong resistance to NaCl, DMSO, and Tween-80, all properties that are required for specific, targeted industrial applications.

Structure-function relationships in human d-amino acid oxidase variants corresponding to known SNPs.

In the brain, d-amino acid oxidase plays a key role in modulating the N-methyl-d-aspartate receptor (NMDAR) activation state, catalyzing the stereospecific degradation of the coagonist d-serine. A relationship between d-serine signaling deregulation, NMDAR dysfunction, and CNS diseases is presumed. Notably, the R199W substitution in human DAAO (hDAAO) was associated with familial amyotrophic lateral sclerosis (ALS), and further coding substitutions, i.e., R199Q and W209R, were also deposited in the single nucleotide polymorphism database. Here, we investigated the biochemical properties of these different hDAAO variants. The W209R hDAAO variant shows an improved d-serine degradation ability (higher activity and affinity for the cofactor FAD) and produces a greater decrease in cellular d/(d+l) serine ratio than the wild-type counterpart when expressed in U87 cells. The production of H2O2 as result of excessive d-serine degradation by this hDAAO variant may represent the factor affecting cell viability after stable transfection. The R199W/Q substitution in hDAAO altered the protein conformation and enzymatic activity was lost under conditions resembling the cellular ones: this resulted in an abnormal increase in cellular d-serine levels. Altogether, these results indicate that substitutions that affect hDAAO functionality directly impact on d-serine cellular levels (at least in the model cell system used). The pathological effect of the expression of the R199W hDAAO, as observed in familial ALS, originates from both protein instability and a decrease in kinetic efficiency: the increase in synaptic d-serine may be mainly responsible for the neurotoxic effect. This information is expected to drive future targeted treatments.

Liquid chromatography-mass spectrometry structural characterization of neo glycoproteins aiding the rational design and synthesis of a novel glycovaccine for protection against tuberculosis.

Hereby we describe a pilot study for the rational design and synthesis of a glycoconjugate vaccine against Tuberculosis (TB) by site-specific coupling of well-defined glycans to non-antigenic amino acids in a selected protein carrier. A combination of ESI-MS and LC-MS analytical methods was applied for the systematic characterization of the reactivity of the surface amino acids in the glycosylation reaction with monosaccharides towards 2-iminomethoxyethyl or homobifunctional (4-nitrophenyl ester) linkers, both on the model protein, ribonuclease A (RNase A) and on TB10.4, the simplest antigenic protein isolated from Mycobacterium tuberculosis (MTB). Intact protein analysis was carried out to quantify the glycosylation degree and profile the glycoform composition of all the prepared neo glycoconjugates, while pronase and chymotriptic digests were analyzed to map and rank the reactivity of protein residues. Neo glycopeptides were purified by on-line porous graphitized carbon solid-phase extraction, separated by hydrophilic interaction liquid chromatography and analyzed by electrospray mass spectrometry (ESI-MS(n)). Significantly, different site specificity and glycosylation efficiency were demonstrated for the two linkers, resulting in structurally diverse glycoconjugates. A computational analysis of the amino acids involved in the epitope formation in TB10.4 addressed the choice to 2-iminomethoxyethyl-saccharide activation, that resulted in a more targeted and selective conjugation preserving the protein antigenicity. Additionally, a rational design of experiments lead to the identification of suitable experimental conditions for the preparation of highly pure and homogeneous neo glycoconjugates.

Novel biosensors based on optimized glycine oxidase.

Glycine is involved in several physiological functions, e.g. as a neurotransmitter in the central nervous system, and sarcosine has been identified as a differential metabolite greatly enhanced during prostate cancer progression and metastasis. Glycine oxidase from Bacillus subtilis (GO) was engineered with the final aim of producing specific analytical systems to detect these small achiral amino acids. Based on in silico analysis, site-saturation mutagenesis was independently performed at 11 positions: a total of 16 single-point GO variants were analyzed. Significantly improved kinetic parameters were observed on glycine for the A54R, H244K-N-Q-R, Y246W and M261R variants. The introduction of multiple mutations then identified the H244K/M261R variant showing a 5.4-fold increase in maximal activity on glycine. With sarcosine as substrate, a number of single-point variants showed increased maximal activity and/or affinity: the kinetic efficiency was increased 6-fold for the M49L variant. Two GO variants with a high substrate specificity ratio for glycine (versus sarcosine, i.e. H244K GO) or for sarcosine (versus glycine, i.e. M49L GO) combined with high substrate affinity were used to set up a simple fluorescence-based biosensor. This optical sensing assay represents a novel, inexpensive and fast tool to assay glycine or sarcosine concentrations in biological samples (detection limit ≤ 0.5 µm).

Optimizing Escherichia coli as a protein expression platform to produce Mycobacterium tuberculosis immunogenic proteins.

BACKGROUND: A number of valuable candidates as tuberculosis vaccine have been reported, some of which have already entered clinical trials. The new vaccines, especially subunit vaccines, need multiple administrations in order to maintain adequate life-long immune memory: this demands for high production levels and degree of purity. RESULTS: In this study, TB10.4, Ag85B and a TB10.4-Ag85B chimeric protein (here-after referred as full)--immunodominant antigens of Mycobacterium tuberculosis--were expressed in Escherichia coli and purified to homogeneity. The rational design of expression constructs and optimization of fermentation and purification conditions allowed a marked increase in solubility and yield of the recombinant antigens. Indeed, scaling up of the process guaranteed mass production of all these three antigens (2.5-25 mg of pure protein/L cultivation broth). Quality of produced soluble proteins was evaluated both by mass spectrometry to assess the purity of final preparations, and by circular dichroism spectroscopy to ascertain the protein conformation. Immunological tests of the different protein products demonstrated that when TB10.4 was fused to Ag85B, the chimeric protein was more immunoreactive than either of the immunogenic protein alone. CONCLUSIONS: We reached the goal of purifying large quantities of soluble antigens effective in generating immunological response against M. tuberculosis by a robust, controlled, scalable and economically feasible production process.

Structural, kinetic, and pharmacodynamic mechanisms of D-amino acid oxidase inhibition by small molecules.

We characterized the mechanism and pharmacodynamics of five structurally distinct inhibitors of d-amino acid oxidase. All inhibitors bound the oxidized form of human enzyme with affinity slightly higher than that of benzoate (Kd ≈ 2-4 µM). Stopped-flow experiments showed that pyrrole-based inhibitors possessed high affinity (Kd ≈ 100-200 nM) and slow release kinetics (k < 0.01 s(-1)) in the presence of substrate, while inhibitors with pendent aromatic groups altered conformations of the active site lid, as evidenced by X-ray crystallography, and showed slower kinetics of association. Rigid bioisosteres of benzoic acid induced a closed-lid conformation, had slower release in the presence of substrate, and were more potent than benzoate. Steady-state d-serine concentrations were described in a PK/PD model, and competition for d-serine sites on NMDA receptors was demonstrated in vivo. DAAO inhibition increased the spatiotemporal influence of glial-derived d-serine, suggesting localized effects on neuronal circuits where DAAO can exert a neuromodulatory role.

Enzymatic detection of D-amino acids.

D: -Amino acids play several key roles and are widely diffused in living organisms, from bacteria (in which D-alanine is a component of the cell wall) to mammals (where D-serine is involved in glutamatergic neurotransmission in the central nervous system). The study of the biological processes involving D-amino acids and their use as clinical or biotechnological biomarkers requires reliable methods of quantifying them. Although "traditional" analytical techniques have been (and still are) employed for such tasks, enzymatic assays based on enzymes which possess a strict stereospecificity (i.e., that are only active on the D-enantiomers of amino acids) allowed the set-up of low-cost protocols with a high sensitivity and selectivity and suitable for determining the D-amino acid content of complex biological samples. The most exploited enzyme in these assays is D-amino acid oxidase, a flavoenzyme that exclusively oxidizes D-amino acids and possesses with a broad substrate specificity and a high kinetic efficiency.