Isolation and culture of gymnosperm root protoplasts (Pinus pinaster)

Various factors affecting the yield and isolation of axenic protoplast cultures originating from Pinus pinaster root segments (in which most cells are differentiating) were studied. In spite of the use of plant material collected from germinating seeds under aseptic conditions, an additional sterilization with 0.1 % w/v mercuric chloride in 50% ethanol was a prerequisite for obtaining an axenic protoplast culture. A pretreatment with 30 mM cysteine in 0.7 M sorbitol for I h tripled the yield. Cen-trifugation at lOOg instead of 40 g further increased the yield to 6 × 103 protoplasts per cm of root segment. Viability ranged from 80 to 91%. Cell divisions occurred after a minimum of 7 days of culture.     

Profiling of in vitro activities of urea-based inhibitors against cysteine synthases from Mycobacterium tuberculosis

CysK1 and CysK2 are two members of the cysteine/S-sulfocysteine synthase family in Mycobacterium tuberculosis, responsible for the de novo biosynthesis of l-cysteine, which is subsequently used as a building block for mycothiol. This metabolite is the first line defense of this pathogen against reactive oxygen and nitrogen species released by host macrophages after phagocytosis. In a previous medicinal chemistry campaign we had developed urea-based inhibitors of the cysteine synthase CysM with bactericidal activity against dormant M. tuberculosis. In this study we extended these efforts by examination of the in vitro activities of a library consisting of 71 urea compounds against CysK1 and CysK2. Binding was established by fluorescence spectroscopy and inhibition by enzyme assays. Several of the compounds inhibited these two cysteine synthases, with the most potent inhibitor displaying an IC₅₀ value of 2.5 µM for CysK1 and 6.6 µM for CysK2, respectively. Four of the identified molecules targeting CysK1 and CysK2 were also among the top ten inhibitors of CysM, suggesting that potent compounds could be developed with activity against all three enzymes.     

Inhibitory Effects of Cysteine and Cysteine Derivatives on Germination of Sporangiospores and Hyphal Growth of Different Zygomycetes

The in vitro antifungal activity of cysteine (d- and l-cysteine) and its four derivatives (l-cysteine-methyl-ester, N-acetyl-cysteine, N-isobutyryl-d-cysteine, and N-isobutyryl-l-cysteine) were investigated on 20 fungal isolates representing 16 genera (Absidia, Actinomucor, Backusella, Gilbertella, Micromucor, Mortierella, Mucor, Mycotypha, Phycomyces, Rhizomucor, Rhizopus, Saksenaea, Syncephalastrum, Thamnostylum, Umbellopsis, and Zygorynchus). The inhibitory potential of different concentrations of these compounds, ranging from 0.625 to 10 mM, were investigated on the germination of sporangiospores as well as on hyphal extension, using broth microdilution method and agar plate test. Treatment with cysteine and its derivatives resulted in a strong inhibition in most studied strains. At 10 mM of compounds, complete blockage of growth was observed for some isolates. Sensitive species exhibited severe changes in colony morphology in the presence of 10 mM l-cysteine, N-acetyl-cysteine, and N-isobutyryl-l-cysteine. Microscopic observations revealed that 10 mM N-acetyl-cysteine induced dramatic modifications in the structural organization of the hyphae. Results suggest that cysteine and its derivatives have a therapeutic potential against fungal infections caused by Zygomycetes species.     

Cystatins – Extra- and intracellular cysteine protease inhibitors: High-level secretion and uptake of cystatin C in human neuroblastoma cells

Cystatins are present in mammals, birds, fish, insects, plants, fungi and protozoa and constitute a large protein family, with most members sharing a cysteine protease inhibitory function. In humans 12 functional cystatins exist, forming three groups based on molecular organisation and distribution in the organism. The type 1 cystatins (A and B) are known as intracellular, type 2 cystatins (C, D, E/M, F, G, S, SN and SA) extracellular and type 3 cystatins (L- and H-kininogen) intravascular proteins. The present paper is focused on the human cystatins and especially those of type 2, which are directed (with signal peptides) for cellular export following translation. Results indicating existence of systems for significant internalisation of type 2 cystatins from the extracellular to intracellular compartments are reviewed. Data showing that human neuroblastoma cell lines generally secrete high levels, but also contain high amounts of cystatin C are presented. Culturing of these cells in medium containing cystatin C at concentrations found in body fluids resulted in increased intracellular cystatin C, as a result of an uptake process. At immunofluorescence cytochemistry a pronounced vesicular cystatin C staining was observed. The simplistic denotation of the type 2 cystatins as extracellular inhibitors is thus challenged, and possible biological functions of the internalised cystatins are discussed. To illustrate the special case of high cellular cystatin content seen in cells of patients with hereditary cystatin C amyloid angiopathy, expression vectors for wild-type and L68Q mutated cystatin C were used to transfect SK-N-BE(2) cells. Clones overexpressing the two variants showed increased secreted levels of cystatin C. Within the cells the L68Q variant appeared to mainly localise to the endoplasmic reticulum rather than to acidic vesicular organelles, indicating limitations in the transport out from the cell rather than increased uptake as explanation for the elevated cellular cystatin levels seen in hereditary cystatin C amyloid angiopathy.     

A critical evaluation of probes for cysteine sulfenic acid

Cysteine oxidation is important in cellular redox regulation, signaling, and biocatalysis. To understand the biological relevance of cysteine oxidation, it is desirable to identify the proteins involved, the site of the oxidized cysteine, and the relevant oxidation states. Because the thiol of cysteine can be converted to a wide range of oxidation states, mapping these oxidative modifications is challenging. The dynamic and reversible nature of many cysteine oxidation states compounds the difficulty in such proteomic analyses. In this review, we examine methods to detect cysteine sulfenic acid — a particularly challenging functional group to analyze because of its reactive nature. We focus on the selectivity of recently reported probes and discuss some challenges and opportunities in this field.     

Cysteine and indole derivatives as markers for malignant melanoma

Malignant melanoma is a skin tumour, which carries a very unfavourable prognosis. The early detection of a melanoma and even more its metastasis is of decisive importance for the survival prognosis of the patients. So there is always a desire for simple, economical and meaningful serological markers. From the cysteine- and indole-related derivatives, 5-S-cysteinyldopa (5-SCD) and 6-hydroxy-5-methoxy-indole-2-carboxylic acid (6H5MI2C) are the most important substances for this purpose. For 5-SCD, the sample pretreatment was carried out either by a manual extraction onto alumina, by an automated method onto boronic acid affinity gels or by an automated solid-phase extraction. For 6H5MI2C, liquid–liquid extractions or direct injection techniques were applied. The chromatographic analyses in the early years were mostly performed with GC–MS. Today HPLC is the nearly exclusively used separation technique. For HPLC, standard RP18 separating columns and usual compositions of eluents were applied. As detectors both the ECD and the FD showed a sufficient sensitivity and selectivity. 5-SCD and 6H5MI2C are very sensitive to light and oxidation. These properties must be taken into account in the complete analysis procedure, including the sample collection, otherwise false low values will result especially for plasma samples. For a critical discussion of the analytical methods and still more for the interpretation of the obtained results, the detailed analytical procedures must be considered. 5-SCD in plasma is one of the best markers of malignant melanoma. It shows an excellent specificity and also an adequate sensitivity in the metastatic melanoma stages. For the detection of primary melanomas and for urine instead of plasma samples, the sensitivity of 5-SCD is generally lower. Altogether, the sensitivity of this parameter is not yet sufficient. 6H5MI2C and other indole derivatives have been investigated far less than 5-SCD. 6H5MI2C correlates less clearly with the different stages of the melanoma and is therefore a less suitable marker. To improve the sensitivity of the findings, in future the investigations should be performed as multi-marker analysis with the simultaneous measurements of more than one marker substance in a given patient sample. Not only one measurement should be carried out per patient, it would be more meaningful to observe the patients with laboratory diagnostics in the follow-up.     

Anaerobic oxidation of cysteine to cystine by manganese(III) in aqueous acetic acid

The anaerobic oxidation of cysteine, Cys, by Mn(III) in acetic acid solutions has been followed by use of a stopped-flow spectrophotometric method at a temperature of 20 °C. The formation and disappearance of the [Mn(OAc)₂Cys]⁻ complex was monitored at 350 nm. The rate depends strongly on the acetic acid concentration (and hence also on pH) and led to the conclusion that more than one cysteine-containing species was involved. These mono-cysteinyl complexes are formed by the loss of two protons from the cysteine - one from the - SH and the other from either the -NH₃⁺ or, more likely, the -COOH which is partially protonated at the low pH values involved (0.5-2.5). The rate-determining reprotonation of the bound -COO⁻ (or -NH₂) is then accompanied by internal electron transfer yielding Mn(II) and the cysteinyl radical, Cys•, which then dimerises to form (inactive) cystine. At high acetic acid concentrations (60-90% AcOH) the tris-acetato species, [Mn(OAc)₃], predominates together with some of the bis-complex, [Mn(OAc)₂]⁺, and the active species is [Mn(OAc)₂Cys]⁻ which decomposes with a rate constant of k₂=16.8±0.9 M⁻¹ s⁻¹. At low acetic acid concentrations (20-30% AcOH) the mono-acetato species predominates and the reactive species is [Mn(OH)Cys] for which the rate of decomposition=k₂^′=(1.32±0.11)×10⁴ M⁻¹ s⁻¹. The relative values of the rate constants obtained are discussed, as is the bonding of cysteine to manganese(III).     

Molecular and biochemical analysis of serine acetyltransferase and cysteine synthase towards sulfur metabolic engineering in plants

Summary. Serine acetyltransferase (SATase) and cysteine synthase (O-acetylserine (thiol)-lyase) (CSase) are committed in the final step of cysteine biosynthesis. Six cDNA clones encoding SATase have been isolated from several plants, e.g. watermelon, spinach, Chinese chive and Arabidopsis thaliana. Feedback-inhibition pattern and subcellular localization of plant SATases were evaluated. Two types of SATase that differ in their sensitivity to the feedback inhibition by l-cysteine were found in plants. In Arabidopsis, cytosolic SATase was inhibited by l-cysteine at a physiological concentration in an allosteric manner, but the plastidic and mitochondrial forms were not subjected to this feedback regulation. These results suggest that the regulation of cysteine biosynthesis through feedback inhibition may differ depending on the subcellular compartment. The allosteric domain responsible for l-cysteine inhibition was characterized, using several SATase mutants. The single change of amino acid residue, glycine-277 to cysteine, in the C-terminal region of watermelon SATase caused a significant decrease of the feedback-inhibition sensitivity of watermelon SATase. We made the transgenic Arabidopsis overexpressing point-mutated watermelon SATase gene whose product was not inhibited by l-cysteine. The contents of OAS, cysteine, and glutathione in transgenic Arabidopsis were significantly increased as compared to the wild-type Arabidopsis. Transgenic tobacco (Nicotiana tabacum) (F₁) plants with enhanced CSase activities both in the cytosol and in the chloroplasts were generated by cross-fertilization of two transgenic tobacco expressing either cytosolic CSase or chloroplastic CSase. Upon fumigation with 0.1 μL L⁻¹ sulfur dioxide, both the cysteine and glutathione contents in leaves of F₁ plants were increased significantly, but not in leaves of non-transformed control plants. These results indicated that both SATase and CSase play important roles in cysteine biosynthesis and its regulation in plants. Received November 27, 2001 Accepted December 21, 2001     

Simplified cysteine dioxygenase activity assay allows simultaneous quantitation of both substrate and product

A high-performance liquid chromatography (HPLC) method for enzyme activity assays using a hydrophilic interaction liquid chromatography (HILIC) column in combination with an evaporative light scattering detector was developed. The method was used to measure the activity of the non-heme mono-iron enzyme cysteine dioxygenase. The substrate cysteine and the product cysteine sulfinic acid are very weak chromophores, making direct ultraviolet (UV) detection without derivatization rather insensitive; moreover, derivatization of cysteine is often not efficient. Using the system described, underivatized substrate and product in samples from cysteine dioxygenase activity assays could be separated and analyzed. Furthermore, it was possible to quantify cysteic acid, the noncatalytic oxidation product of cysteine sulfinic acid. Acetone was used both to stop the enzymatic reaction by protein precipitation and as an organic mobile phase, making sample preparation very easy and the assay highly reproducible.     

Is a certain amount of cysteine prerequisite to produce brain damage in neonatal rats?

In this study, various manipulations were used to determine if certain amounts of cysteine are essential to damage the neonatal rat brain. The information gathered from this study indicated that concentration of free cysteine may be 0.6 mol/g of wet brain weight or more to cause the toxicity to produce the brain damage, and the results were discussed in the light that free cysteine might itself be the cause of brain damage.     

Functional analysis of the Bacillus subtilis cysK and cysJI genes

The function of the Bacillus subtilis cysK and cysJI (previously designated yvgQR) genes, expected to be involved in the assimilatory sulfate reduction pathway, was investigated. A B. subtilis mutant with a deletion in the cysJI genes was unable to use sulfate or sulfite as sulfur source, which confirmed that these genes encode sulfite reductase. A mutant with a transposon insertion in the cysK gene, whose deduced protein sequence showed similarity to cysteine synthases, grew poorly on sulfate and butanesulfonate. A strain in which cysK and yrhA, a cysK paralog, were inactivated was unable to grow with sulfate. Whereas expression of the cysJI genes was induced by sulfate, expression of cysK was repressed both by sulfate and by cysteine.     

Effect of glucose-cysteine adduct as a cysteine prodrug in rats

Summary Effect of intraperitoneal administration (5 mmol/kg of body weight) of glucose- cysteine adduct (glc-cys) as a cysteine prodrug in rat tissues was studied. Cysteine levels in liver and kidney increased to 1.08 and 1.98mol per g or ml, respectively, at 2h after the administration. GSH levels did not change substantially. However, when glc-cys was injected to rats treated with diethyl maleate, a GSH-depleting agent, the decreased GSH levels were restored rapidly. The recoveries in liver and kidney were 72% at 1h and 66% at 2h, respectively, after glc-cys administration. Metabolism of glc-cys was assessed by urinary excretion of glc-cys, sulfate and taurine. Average excretion of glc-cys was 2.86mmol/kg/24h after glc-cys administration. Increased excretions of sulfate and taurine were 0.77 and 0.14mmol/kg/24h, respectively. Data show that, although glc-cys excretion was relatively rapid, glc-cys was effectively utilized for GSH synthesis in GSH-depleted tissues.     

The outer membrane TolC is involved in cysteine tolerance and overproduction in <Emphasis Type="Italic">Escherichia coli</Emphasis>

l-Cysteine is an important amino acid in terms of its industrial applications. We previously found marked production of l-cysteine directly from glucose in recombinant Escherichia coli cells by the combination of enhancing biosynthetic activity and weakening the degradation pathway. Further improvements in l-cysteine production are expected to use the amino acid efflux system. Here, we identified a novel gene involved in l-cysteine export using a systematic and comprehensive collection of gene-disrupted E. coli K-12 mutants (the Keio collection). Among the 3,985 nonessential gene mutants, tolC-disrupted cells showed hypersensitivity to l-cysteine relative to wild-type cells. Gene expression analysis revealed that the tolC gene encoding the outer membrane channel is essential for l-cysteine tolerance in E. coli cells. However, l-cysteine tolerance is not mediated by TolC-dependent drug efflux systems such as AcrA and AcrB. It also appears that other outer membrane porins including OmpA and OmpF do not participate in TolC-dependent l-cysteine tolerance. When a low-copy-number plasmid carrying the tolC gene was introduced into E. coli cells with enhanced biosynthesis, weakened degradation, and improved export of l-cysteine, the transformants exhibited more l-cysteine tolerance and production than cells carrying the vector only. We concluded that TolC plays an important role in l-cysteine tolerance probably due to its export ability and that TolC overexpression is effective for l-cysteine production in E. coli. Natthawut Wiriyathanawudhiwong and Iwao Ohtsu contributed equally to this work.     

Alteration of Cerebral Taurine Biosynthesis in Spontaneously Hypertensive Rats

Abstract: Cerebral taurine biosynthesis in a spontaneously hypertensive rat (SHR) has been studied. Cysteine sulfinic acid (CSA) and cysteic acid (CA), possible key intermediates in taurine biosynthesis, were found in the rat brain, whereas no cysteamine-cystamine was detected. In the brain of SHR, a statistically significant decrease in the contents of CSA, CA, and taurine was noted in the cerebellum, hypothalamus, and striatum as compared with normotensive Wistar Kyoto rats. Similarly, it was demonstrated that the activity of cysteine dioxygenase, the enzyme catalyzing cysteine to CSA, was attenuated significantly in the same brain areas of SHR. In contrast, no alteration in the activity of CSA decarboxylase, the enzyme converting CSA to hypotaurine or CA to taurine, was observed. A decline in the percent conversion of [¹⁴C]cysteine to [¹⁴C]taurine was found also in tissue homogenates from the cerebellum, hypothalamus, and striatum of SHR, indicating that the declines in taurine content may be due to an attenuation of taurine biosynthesis, possibly at the step involving cysteine dioxygenase.     

Biochemical properties and regulation of cathepsin K activity

Cysteine cathepsins (11 in humans) are mostly located in the acidic compartments of cells. They have been known for decades to be involved in intracellular protein degradation as housekeeping proteases. However, the discovery of new cathepsins, including cathepsins K, V and F, has provided strong evidence that they also participate in specific biological events. This review focuses on the current knowledge of cathepsin K, the major bone cysteine protease, which is a drug target of clinical interest. Nevertheless, we will not discuss recent developments in cathepsin K inhibitor design since they have been extensively detailed elsewhere. We will cover features of cathepsin K structure, cellular and tissue distribution, substrate specificity, and regulation (pH, propeptide, glycosaminoglycans, oxidants), and its putative roles in physiological or pathophysiological processes. Finally, we will review the kinetic data of its inhibition by natural endogenous inhibitors (stefin B, cystatin C, H- and L-kininogens).     

Formation of 8-S-l-cysteinylguanosine from 8-bromoguanosine and cysteine

When 8-bromoguanosine was incubated with cysteine at pH 7.4 and 37 °C, a previously unidentified product was formed as a major product in addition to guanosine. The product was identified as a cysteine substitution derivative of guanosine at the 8 position, 8-S-l-cysteinylguanosine. The reaction was accelerated under mildly basic conditions. The cysteine adduct of guanosine was fairly stable and decomposed with a half-life of 193 h at pH 7.4 and 37 °C. Similar results were observed for incubation of 8-bromo-2′-deoxyguanosine with cysteine. The results suggest that 8-bromoguanine in nucleosides, nucleotides, RNA, and DNA can react with thiols resulting in stable adducts.     

Thiols in the Melanocyte

Melanocytes contain several substances formed by the nucleophilic addition of cysteine to dopaquinone. 5-S-Cysteinyldopa is the quantitatively dominant catecholic amino acid belonging to this group of compounds. Glutathione is the thiol most abundantly present in all cells studied, and the reactivity of the SH-group of this tripeptide with dopaquinone is about one-third that of cysteine. However, the amount of glutathionyldopa is at least two orders of magnitude less than that of cysteinyldopa in the melanocyte. A rapid metabolism of glutathionyldopa has therefore been suggested as an explanation for the above-mentioned findings. The enzyme responsible for hydrolysis of the γ-glutamyl bond of glutathione, γ-glutamyltranspeptidase, is present in the melanocyte, but in small quantities. Furthermore, S-cysteinylglycinyldopa, which is the product of hydrolysis by γ-glutamyltranspeptidase, is found in only very small amounts. These facts taken together contradict the hypothesis that S-cysteinyldopas in the melanocyte are formed from S-glutathionyldopas. The present investigation on IGR1 melanoma cells was performed by in situ derivatization of thiols with monobromobimane. Quantitation of the stable bimane adducts of cysteine and glutathione was achieved by reverse-phase high-performance liquid chromatography with fluorimetric detection. The concentration of reduced cysteine in the melanocytes was found to be a few percent of that of reduced glutathione. The quantities of 5-S-cysteinyldopa, 5-S-glutathionyldopa, cysteine, and glutathione observed in the cultured melanoma cells could best be explained by a pronounced compartmentalization of cysteine within the melanocyte, with a high cysteine concentration at the site of the dopaquinone formation.     

Human and bovine brain cathepsin L and cathepsin H: Purification,physico-chemical properties,and specificity

Cathespin L (EC 3.4.22.15) and cathepsin H (EC 3.4.22.16) have been purified from brain cortex to apparent homogeneity by a simultaneous procedure involving acid extraction of homogenate at pH 4.2, ammonium sulfate fractionation (30–80%), chromatography on pepstatin-Sepharose, CM-Sephadex C-50, DEAE-Sephadex A-50, phenyl- and concanavalin A-Sepharose and isoelectric focusing. Cathepsin L and cathepsin H were assayed in the presence of dithiothreitol and Na₂EDTA (2 mM each) with Z-Phe-Arg-NHMec (pH 5.5) and Lys-NNa (pH 6.5) respectively. Cathepsin L consists of 2 polypeptide chains with M_r 25 000 and 5 000, M_r of cathepsin H is 28 000. Cathepsin L exists in brain tissue in two multiple forms with pI values 5.7 and 5.9, pI of cathepsin H is 6.8. Substrate specificity of these thiol proteinases was tested with proteins (pyridoxyl-hemoglobin, azocasein) and low M_r naphthylamide and methylcoumarylamide substrates: Lys-NNa, Arg-NNa, Dz-Arg-NNa, Z-Arg-Arg-NNaOMe, Z-Phe-Arg-NHMec, Z-Phe, Val-Arg-NHMec, Z-Gly-Gly-Arg-NHMec. Z-Phe-Arg-NHMec is the best substrate for cathepsin L (K_M=5 M, K_cat=21 s^–1), Arg-NNa—for cathepsin H (K_M=0.1 mM, K_cat=1.93 s^–1), being endoaminopeptidase cathepsin H also hydrolyses Bz-Arg-NNa (K_M=0.7 mM, K_cat=1.3 s^–1). Both proteinases are inhibited by traditional inhibitors of cysteine proteinases and E-64, but leupeptin turned to be more effective inhibitor of cathepsin L (K_i=2.4 nM) than of cathepsin H (K_i=9.2 M), the latter enzyme being sensitive to puromycin and benzethonium chloride as well. Z-Phe-Phe-CHN₂ and Z-Phe-Ala-CHN₂ are potent irreversible inhibitors of brain cathepsin L with K_2nd 150 000 and 137 000 M^–1 s^–1 respectively. Properties of the enzymes from human and bovine brain are similar.Special Issue Dedicated to Dr. Abel Lajtha.