Acrylamide in fried and roasted potato products: A review on progress in mitigation

The workshop of the European Commission and the Confederation of the Food and Drink Industries of the European Union (CIAA) held in March 2006 in Brussels, Belgium, discussed the key knowledge and achievements in the mitigation of acrylamide. This paper presents the progress made by the potato sector and identifies areas for future research. Because of the important contribution of potato products to acrylamide intake, it is an area that has received much attention. The discovery of the method of formation and the role of reducing sugars meant that long-standing knowledge in respect of sugar and fry colour could be used to identify methods of mitigation. Improvement in parameters such as (1) potato variety, (2) potato storage temperature, (3) process control (thermal input, pre-processing), (4) final preparation, and (5) colour have all contributed to a significant overall reduction in the average acrylamide content in French fries and potato crisps (termed 'chips' in the USA). There is evidence that the limit of reduction that these measures can offer for crisps has now been approached, but clearly more can be done for French fries and roasted potato products. The use of asparaginase offers potentially significant reduction in certain prefabricated potato products. More research is required into new potato varieties and the agronomical factors that influence the levels of asparagine and sugars in potatoes.

Acrylamide in coffee: Review of progress in analysis, formation and level reduction

This paper summarizes the progress made in understanding the formation of acrylamide in coffee, as well as potential reduction strategies, as presented during the joint CIAA/EC workshop on acrylamide, held in Brussels in March 2006. Currently, there are no concrete measures to reduce acrylamide concentrations in roast and ground coffee without appreciably changing the organoleptic properties of the product. Certain approaches, such as steam roasting, have been tried on a laboratory scale, albeit without affording a significant reduction. More work on the mechanisms governing the "loss" of acrylamide during storage of roast and ground coffee is warranted, and studies in this direction have been initiated. Finally, risk/benefit analysis must be addressed in a complex food such as coffee, known to harbour numerous health beneficial/chemoprotective compounds with antioxidant and antimutagenic properties.

Molecular characterization of the soybean L-asparaginase gene induced by low temperature stress

L-asparaginase (EC 3.5.1.1) catalyzes the hydrolysis of the amide group of L-asparagine, releasing aspartate and NH4+. We isolated a low temperature-inducible cDNA sequence encoding L-asparaginase from soybean leaves. The full-length L-asparaginase cDNA, designated GmASP1, contains an open reading frame of 1,258 bp coding for a protein of 326 amino acids. Genomic DNA blotting and fluorescence in situ hybridization showed that the soybean genome has two copies of GmASP1. GmASP1 mRNA was induced by low temperature, ABA and NaCl, but not by heat shock or drought stress. E. coli cells expressing recombinant GmASP1 had 3-fold increased L-asparaginase activity. A possible function of L-asparaginase in the early response to low temperature stress is discussed.

Crystal structure and allosteric regulation of the cytoplasmic Escherichia coli L-asparaginase I

AnsA is the cytoplasmic asparaginase from Escherichia coli involved in intracellular asparagine utilization. Analytical ultracentifugation and X-ray crystallography reveal that AnsA forms a tetrameric structure as a dimer of two intimate dimers. Kinetic analysis of the enzyme reveals that AnsA is positively cooperative, displaying a sigmoidal substrate dependence curve with an [S](0.5) of 1 mM L-asparagine and a Hill coefficient (n(H)) of 2.6. Binding of L-asparagine to an allosteric site was observed in the crystal structure concomitant with a reorganization of the quarternary structure, relative to the apo enzyme. The carboxyl group of the bound asparagine makes salt bridges and hydrogen bonds to Arg240, while the N(delta2) nitrogen interacts with Thr162. Mutation of Arg240 to Ala increases the [S](0.5) value to 5.9 mM, presumably by reducing the affinity of the site for L-asparagine, although the enzyme retains cooperativity. Mutation of Thr162 to Ala results in an active enzyme with no cooperativity. Transmission of the signal from the allosteric site to the active site appears to involve subtle interactions at the dimer-dimer interface and relocation of Gln118 into the vicinity of the active site to position the probable catalytic water molecule. These data define the structural basis for the cooperative regulation of the intracellular asparaginase that is required for proper functioning within the cell.

Tailoring structure-function properties of L-asparaginase: engineering resistance to trypsin cleavage

Bacterial L-ASNases (L-asparaginases) catalyse the conversion of L-asparagine into L-aspartate and ammonia, and are widely used for the treatment of ALL (acute lymphoblastic leukaemia). In the present paper, we describe an efficient approach, based on protein chemistry and protein engineering studies, for the construction of trypsin-resistant PEGylated L-ASNase from Erwinia carotovora (EcaL-ASNase). Limited proteolysis of EcaL-ASNase with trypsin was found to be associated with a first cleavage of the peptide bond between Lys53 and Gly54, and then a second cleavage at Arg206-Ser207 of the C-terminal fragment, peptide 54-327, showing that the initial recognition sites for trypsin are Lys53 and Arg206. Site-directed mutagenesis of Arg206 to histidine followed by covalent coupling of mPEG-SNHS [methoxypoly(ethylene glycol) succinate N-hydroxysuccinimide ester] to the mutant enzyme resulted in an improved modified form of EcaL-ASNase that retains 82% of the original catalytic activity, exhibits enhanced resistance to trypsin degradation, and has higher thermal stability compared with the wild-type enzyme.

L-asparaginase and L-glutaminase activities in submerged rice soil amended with municipal solid waste compost and decomposed cow manure

The field study was conducted to evaluate the effect of municipal solid waste compost (MSWC) as a soil amendment on L-asparaginase (LA) and L-glutaminase (LG) activities. Experiments were conducted during the wet seasons of 1997, 1998 and 1999 on rice grown under a submerged condition, at the Agriculture Experimental Farm, Calcutta University at Baruipur, West Bengal, India. The treatments consisted of control, no input; MSWC, at 60 Kg N ha(- 1); well-decomposed cow manure (DCM), at 60 Kg N ha(- 1); MSWC (30 Kg N ha(- 1)) + Urea (U) (30 Kg N ha(- 1)); DCM (30 Kg N ha(- 1)) + U (30 Kg N ha(- 1)) and Fertilizer, (at 60:30:30 NPK kg ha(- 1)) through urea, single superphosphate and muriate of potash respectively). LA and LG activities alone and their ratio with organic-C (ratio index value, RIV), straw and grain yield were higher in DCM than MSWC-treated soils, due to higher amount of biogenic organic materials like water-soluble organic carbon, carbohydrate and mineralizable nitrogen in the former. The studied parameters were higher when urea was integrated with DCM or MSWC, compared to their single applications. The heavy metals in MSWC did not detrimentally influence the above-measured activities of soil. In the event of long term MSWC application, changes in soil quality parameters should be monitored regularly, since heavy metals once entering into soil persist over a long period.

Single QTL mapping and nucleotide-level resolution of a physiologic trait in wine Saccharomyces cerevisiae strains

Natural Saccharomyces cerevisiae yeast strains exhibit very large genotypic and phenotypic diversity. However, the link between phenotype variation and genetic determinism is still difficult to identify, especially in wild populations. Using genome hybridization on DNA microarrays, it is now possible to identify single-feature polymorphisms among divergent yeast strains. This tool offers the possibility of applying quantitative genetics to wild yeast strains. In this instance, we studied the genetic basis for variations in acetic acid production using progeny derived from two strains from grape must isolates. The trait was quantified during alcoholic fermentation of the two strains and 108 segregants derived from their crossing. A genetic map of 2212 markers was generated using oligonucleotide microarrays, and a major quantitative trait locus (QTL) was mapped with high significance. Further investigations showed that this QTL was due to a nonsynonymous single-nucleotide polymorphism that targeted the catalytic core of asparaginase type I (ASP1) and abolished its activity. This QTL was only effective when asparagine was used as a major nitrogen source. Our results link nitrogen assimilation and CO(2) production rate to acetic acid production, as well as, on a broader scale, illustrating the specific problem of quantitative genetics when working with nonlaboratory microorganisms.

Probing the antigenicity of E. coli L-asparaginase by mutational analysis

A strategy, termed alanine-scanning mutagenesis, was used to identify the amino acid residues which are critical to the antigenicity of Escherichia coli L-asparaginase (L-ASP). Three continuous alkaline residues, 195RKH197, were mutated to Ala selectively. Four mutant recombinant L-ASPs were constructed and expressed in E. coli, and then purified. The purified mutants showed a single band by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and were more than 95% pure by reverse high-performance liquid chromatography. The activities of wild-type and mL-ASPs in the fermentative medium were all about 130 U/mL. The change from 195RKH197 to 195AAA197 reduced the antigenicity of the enzyme greatly as shown in competition enzyme-linked immunosorbent assay using polyclonal antibodies raised against the wild-type L-ASP from rabbits. The results show that residues 195RKH197 of E. coli L-ASP are critical to its antigenicity.

Coordination of PsAS1 and PsASPG expression controls timing of re-allocated N utilization in hypocotyls of pine seedlings

During pine seed germination, a large amount of N mobilized from the storage proteins is re-allocated in the hypocotyl as free asparagine, as a result of the high levels of asparagine synthetase (AS) encoded by the PsAS1 gene. To determine the role of this re-allocated N reserve, a full-length cDNA encoding L: -asparaginase (ASPG) has been cloned from Scots pine (Pinus sylvestris L.) seedlings and characterized. Like other N-terminal nucleophile hydrolases, pine ASPG requires a post-translational processing to exhibit enzymatic activity. However, in contrast to previous reports on other plant ASPGs, purified recombinant pine ASPG does not undergo autoproteolytic cleavage in vitro. Our results suggest that the processing requires accessory proteins to assist in the proteolysis or in the proper folding before autocleavage in a divalent cation-dependent manner. Sequence comparison analysis revealed that the pine protein is included in the K+-dependent subfamily of plant ASPGs. The expression of the ASPG-encoding gene (PsASPG) was higher in organs with extensive secondary development of the vascular system. The increase in transcript abundance observed at advanced stages of hypocotyl development was concomitant with a decrease of PsAS1 transcript abundance and a remarkable increase in the number of xylem elements and highly lignified cell walls. These results, together with the precise localization of PsASPG transcripts in cells of the cambial region, suggest that the expression of PsAS1 and PsASPG is temporally coordinated, to control the re-allocation of N from seed storage proteins toward the hypocotyl to be later used during early development of secondary vascular system.

Studies on L-asparaginase enzyme of actinomycetes isolated from estuarine fishes

Actinomycetes were isolated from different organs viz. skin, gills and gut contents of three species of fishes viz. Mugil cephalus (Linnaeus, 1758), Chanos chanos (Forskal, 1775) and Etroplus suratensis (Bloch, 1780) using three different media from the Vellar estuary, situated along the southeast coast of India. Among the three fishes, M. cephalus harboured highest number of actinomycetes population in all the three body parts examined followed by C. chanos and E. suratensis. Out of the three body parts of all fishes, gut contents had highest actinomycetes population followed by gills and skin. Among the three media used for isolation of actinomycetes, Kuster's agar medium was found to be suitable than the starch casein agar and glucose asparagine agar media. Out of the 40 strains isolated, only six strains (LA-2, LA-8, LA-15, LA-20, LA-29 and LA-35) showed significant L-asparagianse activity and were taken up for further studies. Impact of various physical and chemical factors such as pH, temperature, sodium chloride concentration, carbon sources and amino acids on the growth of actinomycetes and L-asparaginase activity was also studied. Optimum growth and enzyme activity was noticed under pH 7 to 8, temperature 37 degrees C, 1-2% sodium chloride concentration, sucrose as carbon source and without any amino acids. Analysis of the cell components of the isolated strains has revealed the wall type-I (the wall type-I is typical for the genus Streptomyces) and the strains were micromorphologically similar to the genus Streptomyces. Hence, the morphological, physiological and biochemical along with the micromorphological results obtained for the L-asparaginase producing strains were compared and the strains were tentatively identified as Streptomyces aureofasciculus (LA-2), S. chattanoogenesis (LA-8), S. hawaiiensis (LA-15), S. orientalis (LA-20), S. canus (LA-29) and S. olivoviridis (LA-35).

Site-Specific PEGylation of Protein Disulfide Bonds Using a Three-Carbon Bridge

The covalent conjugation of a functionalized poly(ethylene glycol) (PEG) to multiple nucleophilic amine residues results in a heterogeneous mixture of PEG positional isomers. Their physicochemical, biological, and pharmaceutical properties vary with the site of conjugation of PEG. Yields are low because of inefficient conjugation chemistry and production costs high because of complex purification procedures. Our solution to these fundamental problems in PEGylating proteins has been to exploit the latent conjugation selectivity of the two sulfur atoms that are derived from the ubiquitous disulfide bonds of proteins. This approach to PEGylation involves two steps: (1) disulfide reduction to release the two cysteine thiols and (2) re-forming the disulfide by bis-alkylation via a three-carbon bridge to which PEG was covalently attached. During this process, irreversible denaturation of the protein did not occur. Mechanistically, the conjugation is conducted by a sequential, interactive bis-alkylation using alpha,beta-unsaturated beta'-monosulfone functionalized PEG reagents. The combination of (a) maintaining the protein's tertiary structure after disulfide reduction, (b) the mechanism for bis-thiol selectivity of the PEG reagent, and (c) the steric shielding of PEG ensure that only one PEG molecule is conjugated at each disulfide bond. PEG was site-specifically conjugated via a three-carbon bridge to 2 equiv of the tripeptide glutathione, the cyclic peptide hormone somatostatin, the tetrameric protein l-asparaginase, and to the disulfides in interferon alpha-2b (IFN). SDS-PAGE, mass spectral, and NMR analyses were used to confirm conjugation, thiol selectivity, and connectivity. The biological activity of the l-asparaginase did not change after the attachment of four PEG molecules. In the case of IFN, a small reduction in biological activity was seen with the single-bridged IFN (without PEG attached). A significantly larger reduction in biological activity was seen with the three-carbon disulfide single-bridged PEG-IFNs and with the double-bridged IFN (without PEG attached). The reduction of the PEG-IFN's in vitro biological activity was a consequence of the steric shielding caused by PEG, and it was comparable to that seen with all other forms of PEG-IFNs reported. However, when a three-carbon bridge was used to attach PEG, our PEG-IFN's biological activity was found to be independent of the length of the PEG. This property has not previously been described for PEG-IFNs. Our studies therefore suggest that peptides, proteins, enzymes, and antibody fragments can be site-specifically PEGylated across a native disulfide bond using three-carbon bridges without destroying their tertiary structure or abolishing their biological activity. The stoichiometric efficiency of this approach also enables recycling of any unreacted protein. It therefore offers the potential to make PEGylated biopharmaceuticals as cost-effective medicines for global use.

Co-occurrence of both L-asparaginase subtypes in Arabidopsis: At3g16150 encodes a K+-dependent L-asparaginase

L-asparaginases (EC 3.5.1.1) are hypothesized to play an important role in nitrogen supply to sink tissues, especially in legume-developing seeds. Two plant L-asparaginase subtypes were previously identified according to their K(+)-dependence for catalytic activity. An L-asparaginase homologous to Lupinus K(+)-independent enzymes with activity towards beta-aspartyl dipeptides, At5g08100, has been previously characterized as a member of the N-terminal nucleophile amidohydrolase superfamily in Arabidopsis. In this study, a K(+)-dependent L-asparaginase from Arabidopsis, At3g16150, is characterized. The recombinants At3g16150 and At5g08100 share a similar subunit structure and conserved autoproteolytic pentapeptide cleavage site, commencing with the catalytic Thr nucleophile, as determined by ESI-MS. The catalytic activity of At3g16150 was enhanced approximately tenfold in the presence of K(+). At3g16150 was strictly specific for L-Asn, and had no activity towards beta-aspartyl dipeptides. At3g16150 also had an approximately 80-fold higher catalytic efficiency with L-Asn relative to At5g08100. Among the beta-aspartyl dipeptides tested, At5g08100 had a preference for beta-aspartyl-His, with catalytic efficiency comparable to that with L-Asn. The phylogenetic analysis revealed that At3g16150 and At5g08100 belong to two distinct subfamilies. The transcript levels of At3g16150 and At5g08100 were highest in sink tissues, especially in flowers and siliques, early in development, as determined by quantitative RT-PCR. The overlapping spatial patterns of expression argue for a partially redundant function of the enzymes. However, the high catalytic efficiency suggests that the K(+)-dependent enzyme may metabolize L-Asn more efficiently under conditions of high metabolic demand for N.

Aspartate transport and metabolism in the protozoan parasite Trypanosoma cruzi

Aspartate is one of the compounds that induce the differentiation process of the non-infective epimastigote stage to the infective trypomastigote stage of the protozoan parasite Trypanosoma cruzi. l-aspartate is transported by both epimastigote and trypomastigote cells at the same rate, about 3.4 pmolmin(-1) per 10(7) cells. Aspartate transport is only competed by glutamate suggesting that this transport system is specific for anionic amino acids. Aspartate uptake rates increase along the parasite growth curve, by amino acids starvation or pH decrease. The metabolic fate of the transported aspartate was predicted in silico by identification of seven putative genes coding for enzymes involved in aspartate metabolism that could be related to the differentiation process.

Asparaginase Display of Human Cholesteryl Ester Transfer Protein (CETP) B Cell Epitopes for Inducing High Titers of Anti-CETP Antibodies In Vivo

The recombinant chimeric enzyme, AnsB-TTP-CETPC, comprising asparaginase, tetanus toxin helper T cell epitope and human CETP B cell epitope was expressed as a soluble protein in Escherichia coli. The purified chimeric enzyme exhibited approximate 83% activity of the native asparaginase. After immunization with three doses of chimeric enzyme, high titers of anti-CETP antibodies were induced and lasted more than eighteen weeks in mice, and could even be detected at a dilution of 1:12800 by normal ELISA assay. The specificity of anti-CETP antibody was verified by Western blot assay. After displaying on the surface of asparaginase, the weak antigenicity of CETP epitope was effectively overcome, there after a strong CETP-specific immune response was evoked in mice immunized with the chimeric enzyme. Histochemical analysis of mice kidney tissue showed that immunization with the chimeric enzyme did not cause any pathological changes in mice. Collectively, the chimeric enzyme may be further developed as a vaccine against atherosclerosis in the future.

[Significance of L-asparaginase activity and biochemical parameters evaluation in children with acute lymphoblastic leukemia]

L-asparaginase is one of the most important agent used in multidrug chemotherapy regimens in the treatment of malignancies which derive from lymphoid system (acute lymhoblastic leukemias and non-hodgkin lymphoma). L-asparaginase leads to enzymatic cleavage of L-asparagine (amino acid essential for lymphoblasts' growth) to ammonia and L-aspartic acid, what results in depletion of L-asparagine in a serum and cerebrospinal fluid, and finally leads to destruction of lymphoblasts, which lack ability of endogenic L-asparagine production. In the course of L-asparaginase therapy severe side effects could be observed such as: coagulation disturbances, acute pancreatitis, anaphilactic shock and other types of allergic reaction, as well as liver and CNS failure. Monitoring of L-asparaginase activity in serum is recomended in order to optimalize therapy with L-asparaginase and reducing risk of severe side effects. Continuous assessment of L-asparaginase activity during therapy gives also opportunity to detect asymptomatic inactivation of L-ASPA - so called "silent inactivation", which is cused by production of antibodies against xenogenic protein, especcialy in IgG class. This process leads to shortening of half-life of L-ASPA. The paper shows presently available monitoring methods during therapy with L-ASPA, with all their pros and cons.

Cloning, expression and characterisation of Erwinia carotovora l-asparaginase

Bacterial L-asparaginases (E.C. 3.5.1.1) have been used as therapeutic agents in the treatment of acute childhood lymphoblastic leukaemia. L-asparaginase from Erwinia carotovora NCYC 1526 (ErA) was cloned and expressed in E. coli. The enzyme was purified to homogeneity by a two-step procedure comprising cation-exchange chromatography and affinity chromatography on immobilised L-asparagine. The enzymatic properties of the recombinant enzyme were investigated and the kinetic parameters (K(m), k(cat)) for a number of substrates were determined. Molecular modelling studies were also employed to create a model of ErA, based on the known structure of the Erwinia chrysanthemi enzyme. The molecular model was used to help interpret biochemical data concerning substrate specificity and catalytic mechanism of the enzyme. The kinetic parameters of selected substrates were determined at various pH values, and the pH-dependence profiles of V(max) and V(max)/K(m) were analyzed. The pH-dependence of V(max) shows one transition in the acidic pH range with pK(a)=5.4, and the pH-dependence of V(max)/K(m) exhibits two transitions with pK(a)=5.4 and 8.5. Based on analysis of alternative substrates and molecular modelling studies, it was concluded that the pK(a) at the acidic pH range corresponds to the active site residues Asp115 or Glu82, whereas the pK(a) observed at the alkaline pH range is not due to substrate amino group ionisation, but rather is the result of enzyme ionisation. The effect of temperature and viscosity on the catalytic activity of the enzyme was also investigated and it was concluded that the rate-limiting step of the catalytic reaction is relevant to structural transitions of the protein. Thermodynamic analysis of the activity data showed that the activation energies are dependent on the substrate, and entropy changes appear to be the main determinant contributing to substrate specificity.

Extracellular expression and single step purification of recombinant Escherichia coli L-asparaginase II

L-Asparaginase (isozyme II) from Escherichia coli is an important therapeutic enzyme used in the treatment of leukemia. Extracellular expression of recombinant asparaginase was obtained by fusing the gene coding for asparaginase to an efficient pelB leader sequence and an N-terminal 6x histidine tag cloned under the T7lac promoter. Media composition and the induction strategy had a major influence on the specificity and efficiency of secretion of recombinant asparaginase. Induction of the cells with 0.1 mM IPTG at late log phase of growth in TB media resulted in fourfold higher extracellular activity in comparison to growing the cells in LB media followed by induction during the mid log phase. Using an optimized expression strategy a yield of 20,950 UI/L of recombinant asparaginase was obtained from the extracellular medium. The recombinant protein was purified from the culture supernatant in a single step using Ni-NTA affinity chromatography which gave an overall yield of 95 mg/L of purified protein, with a recovery of 86%. This is approximately 8-fold higher to the previously reported data in literature. The fluorescence spectra, analytical size exclusion chromatography, and the specific activity of the purified protein were observed to be similar to the native protein which demonstrated that the protein had folded properly and was present in its active tetramer form in the culture supernatant.

[Effects of salinity stress on poplars seedling growth and soil enzyme activity]

A pot culture experiment with two clones of poplars (P1 and P2) showed that soil salinity had a definite inhibitory effect on the establishment and growth of seedlings. The survival rate, seedling height and weight, and root weight were all declined with increasing soil salinity. When the salinity was 0.2%, 0.4%, 0.6% and 0.8%, the shoot growth of P1 and P2 decreased by 23.24%, 48.56%, 70.76% and 83.33%, and 71.77%, 83.25%, 86.28% and 91.39%, respectively, in comparing with the control. Regressive analyses showed that soil salinity had a linear relationship with chlorophyll content, and a binomial relationship with leaf proline content. The activities of soil beta-glucosidase and L-asparaginase were decreased with increasing soil salinity. When the salinity was 0.2%, 0.4%, 0.6% and 0.8%, the beta-glucosidase activity in P1 and P2 soils decreased by 10.96%, 20.07%, 30.96% and 37.44%, and 11.21%, 18.94%, 34.89% and 41.31%, respectively. The salinity tolerance of P1 was better than that of P2.

[X-ray microanalysis of the activity of immobilized L-asparaginase]

The localization of activity of immobilzed L-asparaginase by covalent binding was studied by X-ray microanalysis. Asparagine and MgCl2 served as substrate and capture agent respectively. Substrate was catalysed by immobilized L-asparaginase to produce NH3, and NH3 was captured by MgCl2 to form precipitate MgNH4PO4. Precipitae was deposited on active site of immobilized L-asparaginase. The results show that the macroporous resins of immobilized L-asparaginase has greater enzyme activity, while distribution of activated enzyme was uniform. Most of activated enzyme was immobilized on the macroporous resins. The optimum condition of localization of activity of immobilized L-asparaginase was studied.

Production and enhanced biological activity of a novel GHRH analog, hGHRH with an N-terminal Pro–Pro extension

Growth Hormone Releasing Hormone (GHRH) is one of the most important hormones in life. Because of its potential clinical importance, its short half-life, and its expensive chemical synthesis, an analog of hGHRH with a prolonged half-life and better activity has been studied for clinical application, especially for the treatment of muscle wasting, type II diabetes, or sleep disorders. The Pro-Pro-hGHRH(1-44) peptide has better activity. The fusion partner gene with 127 amino acid residues of the C-terminus from l-asparaginase was recombined with asp-pro-pro-hGHRH(1-44) gene synthesized by PCR method to form a fusion protein with the unique acid labile linker Asp-Pro. The recombinant protein was expressed to high levels in Escherichia coli BL21 (DE3). The Pro-Pro-hGHRH(1-44) peptide was purified to homogeneity by means of cell disruption, washing, ethanol precipitation, acid hydrolysis, and SP-Sephadex C-25, and Sephadex G-25 column chromatography. The fold of the purification was about 88 times and the yield was 1.1% of the total protein weight of the inclusion body. The peptide molecular mass of 5235.25 Da was determined by ESI mass spectroscopy. Its purity was determined by SDS-PAGE. In the study of the activity, we measured GH release of rat pituitary by using the antiserum kit against human GH. The peptide doses of 0.01, 0.1, 1.0, 7.72, and 20.9 microg/ml used, respectively, released the GH values of 0.1+/-0.1, 12.5+/-7.3, 16.6+/-5.8, 49.8+/-7.6, and 79.5+/-5.7 ng/ml whereas their blank controls, respectively, were 0.5+/-0.8, 4.1+/-2.6, 3.1+/-3.1, 4.7+/-1.8, and 1.2+/-0.3 ng/ml. The activity results of all dose groups except 0.01 microg/ml Pro-Pro-hGHRH(1-44) group and hGHRH(1-40) group showed that there were significant differences between GH released by the peptide and that by its blank control. With the increase of dosage, the differences were more significant. hGHRH(1-40) showed no measured GH release when the dose was up to 2 microg/ml. The activity results show that the Pro-Pro-hGHRH(1-44) peptide is a potential GH releasing analog.

l-Asparagine depletion levels and l-asparaginase activity in plasma of children with acute lymphoblastic leukemia under asparaginase treatment

PURPOSE

To determine the minimum levels of L-asparaginase (ASNase) activity necessary to maintain L-asparagine (Asn) depletion under ASNase treatment in acute lymphoblastic leukemia (ALL).

METHODS

We measured ASNase activity using an enzyme coupling method with a limit of detection of 2 U/l and examined the relationship between ASNase activity and Asn levels in blood samples from 14 children with ALL.

RESULTS

In all but one patient showing high ASNase antibody titers, minimum ASNase activity to maintain Asn depletion levels below the limit of detection (40 ng/ml) ranged from 6 to 180 U/l with a median value of 16 U/l. In 11 patients, the enzyme activity corresponding to minimum detectable Asn levels ranged from 2 to 32 U/l with a median value of 6.5 U/l. Patients with an ASNase activity of 2 U/l or an undetectable activity (<2 U/l) had nearly normal Asn levels: 4140+/-1161 ng/ml at 2 U/l and 7235+/-3107 ng/ml at <2 U/l (mean+/-SD). Statistical analysis showed that ASNase activity in the range of 2-32 U/l was inversely correlated with Asn levels ( r=-0.803, P=0.001).

CONCLUSION

These results show that Asn levels are strongly correlated with plasma ASNase activity even at low enzyme activities (<50 U/l) and that this sensitive ASNase assay can be used to estimate plasma Asn depletion levels.

Molecular cloning of a novel human gene encoding histone acetyltransferase-like protein involved in transcriptional activation of hTERT

To isolate proteins involved in hTERT transcriptional regulation, the HeLa cDNA library was screened using the hTERT promoter-based yeast one-hybrid assay. A positive clone was rescued and proved to contain an open reading frame and the upstream coding sequences were obtained by 5'-RACE. The assembled full cDNA consisted of a 2.5 kb reading frame encoding 834 amino acids, in which a conserved N-acetyltransferase domain (GNAT family) was searched out in bioinformatics, and thus named as hALP (human N-acetyltransferase-like protein, GenBank Accession No. AF 489535). The expression of native hALP was identified in HeLa cells and proved to distribute in the cellular nucleus. The binding potential of hALP to hTERT promoter was confirmed by EMSA and the interacting sequence involved to -201- to -56-nt upstream region of the promoter. On transfection assay, hALP could obviously transactivate hTERT promoter and stimulate endogenous telomerase activity of cells. The analysis on histone acetyltransferase showed that hALP could specifically acetylate free histones in vitro. The investigation suggested that hALP influences the activity of histone acetylation and could up-regulate telomerase activity through transactivation of hTERT promoter.