Influence of gradual adaptation of cattle to Leucaena leucocephala leaf meal on biodegradation of mimosine and 3- hydroxy-4(1H)-pyridone (3,4 DHP) in rumen,their levels in blood,fate and influence of absorbed DHP on thyroid hormones and liver enzymes

Three rumen fistulated Karan Fries crossbred (Holstein X Tharparkar) calves were fed increasing dry matter (DM) levels of 25%, 50%, 75% and 100% through leucaena leaf meal (LLM) starting at week 1, 2, 3 and 4, respectively. The mimosine, 3,4 DHP and 2,3 DHP levels were determined in strained rumen liquor (SRL) and serum at 0, 1, 2, 4, 8, 12 and 24 h postfeeding on days 1, 8, 15, 22, 29 and 42. LLM was incubated for 24 h with SRL in vitro on days 0, 7, 14, 21, 28 and 41 to study mimosine and dihydroxypyridone (DHP) biodegradation. On day 43, 1–1.5 l of rumen liquor was transferred to another set of three unadapted calves which were fed 50% LLM after transfer of inoculum. DM intake was 1.78%, 2.13%, 2.27%, 1.66%, 1.54% and 1.35% of live weight during the 1st through 5th week, respectively. Both in vitro and in vivo studies showed extensive degradation of mimosine to 3,4 DHP and 2,3 DHP from first day of LLM feeding. The overall in vitro DHP degradation was nil, 28.6%, 43.3% and 40.1% on day upto 15, 21, 28 and 42 of LLM feeding. No mimosine was found in serum on any day of sampling. The 3,4 DHP detected (56.94±31.65 μg ml⁻¹ serum) one hour post feeding on day 1 exhibited a decline from day 22 onwards. The serum also contained 2,3 DHP on days 8, 15, 22, 42. The faecal and urinary excretion of 3,4 DHP and 2,3 DHP as percent of mimosine intake declined from first week (76.3±2.8) to 4th week (42.1±4.1). The feeding of LLM resulted in reduced level of T₃ and T₄ within a week of LLM feeding. The level of T₃ improved to normal by 6th week while that of T₄ remained low. The SGOT and SGPT activities were within normal range. The gradual adaptation to LLM feeding caused Karan Fries calves to acquire DHP degrading ability to nontoxic compounds and this ability was transferred through transfer of rumen liquor from such calves to other unadapted calves at as early as 9th day of LLM feeding. The results revealed the possibility of two types of microbes degrading mimosine and 3,4 DHP to 2,3 DHP. One type of 2,3 DHP degrading microbes may be inhibited in the presence of 3,4 DHP whereas the other type may be active.     

Growth performance of,and mimosine excretion by,young chicks fed on leucaena leucocephala

Growth performance and mimosine output in excreta have been measured in young chicks fed on diets containing three forms of Leucaena leaf meal (LLM) imported from Malawi. In one of the experiments, the effects of supplementation of LLM with selected metal ions and enzymes were also measured. Growth and efficiency of food utilisation were similar in groups fed on a control soya bean meal diet or a basal diet containing 150 g kg^?1 of the whole leaf (WL) form of LLM. Supplementation of this basal LLM diet with FeSO₄ or Al₂(SO₄)₃ had little effect on growth or efficiency of food utilisation, but the ratio of mimosine output to mimosine ingested (MO/MI) increased from 0.781 to 0.881 and 1.003 on addition of FeSO₄ and Al₂(SO₄)₃, respectively. Growth performance was unaffected by the addition of an enzyme mixture (containing cellulase, acid and neutral proteases and alpha amylase) to the basal LLM diet. In the second experiment, two other forms of LLM were also tested: a ground leaf (GL) form, and a powder produced by grinding pellets of Leucaena leaf (GP). The WL and GP forms were each added at 50 and 100 g kg^?1 diet, and the GL form at 100 g kg^?1 diet. These diets permitted daily intakes of mimosine ranging from 80 to 350 mg per replicate of 4 chicks. In comparison with control groups, growth performance was not impaired significantly in any of the LLM-fed groups. Mimosine excretion was high in all LLM-fed groups, the GP form inducing a maximum MO/MI ratio of 0.924.     

Fate of mimosine administered orally to sheep and its effectiveness as a defleecing agent.

Mimosine was administered orally to Merino sheep once daily for periods of 1-3 days, either as the isolated compound or in the foliage of Leucaena leucocephala. A single daily dose of mimosine of 450 or 600 mg/kg body weight was effective for defleecing sheep. A daily dose rate of 300 mg/kg was effective for defleecing sheep if given on two successive days. The effectiveness of a treatment for defleecing sheep was related to the concentration of mimosine in plasma following dosing; defleecing ensued when the concentration of mimosine in plasma was maintained above 0-1 mmol/l for at least 30 h. The main products excreted in urine were mimosine and 3,4-dihydroxypyridine (DHP); small amounts of mimosinamine were also excreted. During the first day following dosing, the major excretory product was mimosine; DHP was an important component during the second and third days. In the three days following the start of dosing, between 32 and 53% of the mimosine given was accounted for as mimosine in the urine. Following an intravenous infusion of mimosine, no DHP was detected in urine; most of the mimosine was excreted intact but a small amount (c. 9%) was excreted as mimosinamine.     

Activation of the Prereplication Complex Is Blocked by Mimosine through Reactive Oxygen Species-activated Ataxia Telangiectasia Mutated (ATM) Protein without DNA Damage

Mimosine is an effective cell synchronization reagent used for arresting cells in late G₁ phase. However, the mechanism underlying mimosine-induced G₁ cell cycle arrest remains unclear. Using highly synchronous cell populations, we show here that mimosine blocks S phase entry through ATM activation. HeLa S3 cells are exposed to thymidine for 15 h, released for 9 h by washing out the thymidine, and subsequently treated with 1 mm mimosine for a further 15 h (thymidine → mimosine). In contrast to thymidine-induced S phase arrest, mimosine treatment synchronizes >90% of cells at the G₁-S phase boundary by inhibiting the transition of the prereplication complex to the preinitiation complex. Mimosine treatment activates ataxia telangiectasia mutated (ATM)/ataxia telangiectasia and Rad3-related (ATR)-mediated checkpoint signaling without inducing DNA damage. Inhibition of ATM activity is found to induce mimosine-arrested cells to enter S phase. In addition, ATM activation by mimosine treatment is mediated by reactive oxygen species (ROS). These results suggest that, upon mimosine treatment, ATM blocks S phase entry in response to ROS, which prevents replication fork stalling-induced DNA damage.     

A Study of Mimosine Toxicity in Plants

Mimosine and 3,4-dihydroxypyridine are inhibitory to the growthof mung bean seedlings. Mimosine inhibition could be reversedby tyrosine or nicotinic acid, but it was reversed by pyridoxalphosphate or ferrous ions. Inhibition due to dihydroxypyridinealso could be reversed by ferrous ions, but not by pyridoxalphosphate. The possible mechanisms of growth inhibition arediscussed. An enzyme is present in extracts of Leucaena seedlings thatdegrades mimosine stoichiometrically to 3,4-dihydroxypyridine,pyruvate, and ammonia. An enzymic breakdown of mimosine is alsocatalysed by extracts of mung bean seedlings. The occurencein Leucaena of dichrostachinic acid and a C-S-Iyase which degradesit to a thiol derivative, pyruvate, and ammonia were described;the latter enzyme was shown to be distinct from the enzyme-splittingmimosine. The substrate specificity, pH optimum, co-factor requirements,and inhibitors of this mimosine C-N-Iyase were investigated.     

Selective determination of mimosine and its dihydroxypyridinyl derivative in plant systems

Summary. Our observations on the growth stimulatory nature of mimosine, (β-(3-hydroxy-4-pyridon-1-yl)-L-alanine), the toxic non-protein plant amino acid, in some model experimental systems, warranted sensitive and selective routine estimations. For the determination of both mimosine and DHP, an indirect spectrophotometric method was developed based on their individual reaction with known excess of DZSAM and by estimating the remaining DZSAM with N-(1-naphthyl)ethylene-diamine (NEDA). The resultant decrease in the secondary coupled product was measured at 540 nm. On equimolar basis, DHP had 40% of the reactivity of mimosine while interference from other relevant compounds was 15–35%. The determination of mimosine and DHP in tissue samples under different physiological conditions was effected after paper chromatographic separation of mimosine and DHP with distinctly differing R_f, from other compounds. The indirect method is superior in terms of absolute selectivity, sensitivity and ease of applicability with linear decreases in absorbance, proportional to increasing concentrations of mimosine from 0.1 to 0.75 μM or DHP from 0.2 to 1.5 μM and with recoveries of 99.2 to 100.5%.     

Determination of mimosine and 3,4-dihydroxypyridine in milk and plasma of goats

A simple method for determination of mimosine and 3,4-dihydroxypyridine (3,4-DHP) in plasma and milk was developed. Milk and plasma, with tyrosine as internal standard, were deproteinized using 9% trichloracetic acid and extracted with diethyl ether. Metabolites were separated by isocratic high-performance liquid chromatography, with 0.02 M orthophosphoric acid (pH 2.5) at 0.5 ml/min and a Hypersil ODS microbore column. Mimosine, 3,4-DHP and tyrosine were detected at 275 nm. The recovery of the mimosine added to the plasma samples 101.6±2.3% and 103.3±1.0% for milk samples. 3,4-DHP recovery for plasma samples was 101.2±0.9% and for milk samples 100.8±1.4%. The reproducibility of the method was evaluated by analyzing six plasma samples and six goat milk samples. The analyses yielded relative standard deviations of 2.65 and 2.82%, respectively.     

Isolation and biological activities of 3-hydroxy-4(1H)-pyridone

3-Hydroxy-4(4H)-pyridone (3,4-DHP), a degraded product of mimosine [β-[N-(3-hydroxy-4-oxypyridyl)]-α-aminopropionic acid], is known to cause goiters, loss of hair, and infertility in animals, but limits of 3,4-DHP on separation and purification have prevented efforts on investigating other toxicity and biological properties of 3,4-DHP. By this study, a novel and simple isolation of 3,4-DHP was developed either from Leucaena leaves using an ion-exchanged resin or mimosine degraded in high temperature (110°C, 6?h). The inhibition of mimosine on the growth of barnyardgrass was approximately fourfold higher (IC₅₀?=?0.04?mg?g^?1) than that of 3,4-DHP (IC₅₀?=?0.15?mg?g^?1). In general, the antifungal activity of mimosine is much stronger than that of 3,4-DHP, but it differs depending on the kind of fungi. The 1,1-diphyenyl-2-picrylhydrazyl (DPPH) radical scavenging activity of 3,4-DHP, in contrast with the growth inhibitory activity, is about fourfold stronger [EC₅₀?=?2.4?mg?g^?1 gallic acid equivalent (GAE)] than that of mimosine [EC₅₀?=?10.3?mg?g^?1 GAE]. This study is the first to report on the herbicidal, antifungal, and antioxidant activities of 3,4-DHP.     

Mimosine, the Allelochemical from the Leguminous Tree Leucaena leucocephala, Selectively Enhances Cell Proliferation in Dinoflagellates

Mimosine, the allelochemical from the leguminous tree Leucaena leucocephala, is toxic to most terrestrial animals and plants. We report here that while mimosine inhibits major phytoplankton groups, it enhances cell proliferation in dinoflagellates. On addition to coastal seawater samples, mimosine is able to confer a growth advantage to dinoflagellates. The use of mimosine will promote the isolation and culture of this group of phytoplankton.     

Mimosine-Induced Apoptosis in C6 Glioma Cells Requires the Release of Mitochondria-Derived Reactive Oxygen Species and p38, JNK Activation

Growth-inhibitory effects of mimosine, a plant amino acid, on rat C6 glioma cells were analyzed. Mimosine markedly inhibited proliferation and induced apoptosis of C6 glioma cells in a dose- and time-dependent manner. Mimosine-mediated apoptosis was accompanied by promoting reactive oxygen species (ROS) generation in mitochondria, and by decreased mitochondrial membrane potential (Δψ), and release of cytochrome c from mitochondria, followed by caspase 3 activation. Furthermore, mimosine increased the phosphorylation level of c-Jun-N-terminal protein kinase and p38, which was the downstream effect of ROS accumulation. Mimosine was confirmed to show profound effects on apoptosis of C6 glioma cells by ROS-regulated mitochondria pathway, and these results bear on the hypothesized potential for mimosine as promising agents in the treatment of malignant gliomas.     

A molecular mechanism for mimosine-induced apoptosis involving oxidative stress and mitochondrial activation

Mimosine, a non-protein amino acid, is mainly known for its action as a reversible inhibitor of DNA replication and, therefore, has been widely used as a cell cycle synchronizing agent. Recently, it has been shown that mimosine also induces apoptosis, as mainly reflected in its ability to elicit characteristic nuclear changes. The present study elucidates the mechanism underlying mimosine’s apoptotic effects, using the U-937 leukemia cell line. We now demonstrate that in isolated rat liver mitochondria, mimosine induces mitochondrial swelling that can be inhibited by cyclosporine A, indicative of permeability transition (PT) mega-channel opening. Mimosine-induced apoptosis was accompanied by formation of hydrogen peroxide and a decrease in reduced glutathione levels. The apoptotic process was partially inhibited by cyclosporine A and substantially blocked by the antioxidant N-acetylcysteine, suggesting an essential role for reactive oxygen species formation during the apoptotic processes. The apoptosis induced by mimosine was also accompanied by a decrease in mitochondrial membrane potential, cytochrome c release and caspase 3 and 9 activation. Our results thus imply that mimosine activates apoptosis through mitochondrial activation and formation of H₂O₂, both of which play functional roles in the induction of cell death. Maher Hallak and Liat Vazana have contributed equally to the work.     

Radiation sensitization of mammalian cells by metal chelators

The cell cycle effects, alteration in radiation response, and inherent cytotoxicity of the metal chelators mimosine, desferrioxamine (DFO), N,N'-bis(o-hydroxybenzyl)-ethylenediamine-N,N'-diacetic acid (HBED), and deferiprone (L1) were studied in exponentially growing Chinese hamster V79 cells. Incubation of cells with 200-1000 microM mimosine for 12 h reduced clonogenic survival to 50-60%, while incubation for 24 h reduced survival further to 0.5%. Mimosine treatment resulted in cell cycle blocks at the G(1)/S-phase border and in S phase. Pulse labeling with 5-bromodeoxyuridine indicated that the S-phase cells ceased to actively replicate DNA after only 2 h of mimosine treatment and were unable to replicate DNA for extended periods. Treatment of V79 cells with 600 microM mimosine for 12 h resulted in radiosensitization, yielding a sensitizer enhancement ratio (SER) of 2.7 +/- 0.3 at the 10% survival level. To study the kinetics of the sensitization, V79 cells were incubated with mimosine for various times up to 12 h and irradiated with a single 10-Gy dose of X rays. It was found that the radiosensitization increased continually up to 8 h (from a 3- to a 100-fold difference in survival) and then reached a plateau after 8 h. Mimosine also equally radiosensitized human lung cancer cells having either a normal or mutated TP53 gene, suggesting a TP53-independent mechanism. To test whether iron binding by mimosine was responsible for the observed radiosensitization, additional experiments were performed using the iron chelators DFO, HBED and L1. V79 cells treated with 500 microM of these agents for 8 h followed by various doses of X rays gave SERs similar to that for mimosine (2.0-2.7). These studies indicate that metal chelators are potent radiosensitizers in V79 and human cells. Importantly, when the DFO was preloaded together with Fe(3+) [Fe(III)-DFO], the radiosensitizing effect was lost. These preliminary findings warrant further studies for the possible application of metal chelators as radiation sensitizers in radiation oncology.     

Mimosine,the Allelochemical from the leguminous tree Leucaena leucocephala,selectively enhances cell proliferation in dinoflagellates

Mimosine, the allelochemical from the leguminous tree Leucaena leucocephala, is toxic to most terrestrial animals and plants. We report here that while mimosine inhibits major phytoplankton groups, it enhances cell proliferation in dinoflagellates. On addition to coastal seawater samples, mimosine is able to confer a growth advantage to dinoflagellates. The use of mimosine will promote the isolation and culture of this group of phytoplankton.     

Oxidative stress during selenium deficiency in seedlings ofTrigonella foenum-graecum and mitigation by mimosine part II. glutathione metabolism

Adaptive alterations in glutathione (GSH) metabolism were studied during oxidative stress induced by selenium (Se) deficiency in germinating seedlings of Trigonella foenum-graecum grown for 72 h and the response to supplementation individually of Se or mimosine was explored. Growth enhancement with improved mitochondrial efficiency was elicited by supplementation of Se at 0.5-0.75 ppm or mimosine at 0.1-0.2 mM. Total thiol and protein levels of mitochondrial and soluble fractions, in general, did not vary significantly with supplementation of either Se or mimosine except that the mitochondrial protein levels in mimosine groups (0.1-0.2 mM) decreased by 20-30%. Mitochondrial glutathione peroxidase (GSH-Px) increased by twofold in activity toward H2O2, cumene hydroperoxide (CHP), and t-butyl hydroperoxide (tBHP) in Se groups, and by 50-60% increase toward H2O2 and CHP but by a twofold enhancement in enzyme activity with tBHP in mimosine groups. Soluble GSH-Px activity increased by 30-40% only in mimosine groups and remained unaltered in Se groups. Glutathione S-transferase activity (GST) in the soluble fraction of both Se and mimosine groups increased dramatically by fivefold to sixfold. Distinct differences were noted in the response of the stressed seedlings toward exposure to Se or mimosine and included a decline in glutathione reductase (GR) activity by 50-60% in both mitochondria and soluble fractions of Se groups and an increase in GR activity of the mitochondria by twofold and of the soluble enzyme activity by 30% in the mimosine groups. Mimosine exposure resulted in a dose-dependent decrease in the gamma-glutamyl transpeptidase levels, but, in contrast, a significant enhancement by 50% was noted in the Se group at 0.75 ppm. The results including the differential response of GR activity to Se or mimosine supplementation are reflective of an effective reductive environment in Se groups and increased turnover of GSH in the presence of mimosine.     

降解有毒的含羞草素和二羟基吡啶化合物的瘤胃细菌

从采食银合欢不引起中毒症状的我国广西北海市涠洲岛的黄牛瘤胃中,分离出4株厌氧细菌.经高效液相色谱分析证实,菌株BR-1,BR-2,BR-5和BR-7能降解有毒的含羞草素(mimosine)、3-羟基-4(1氢)吡啶酮(3,4 DHP)和2,3-二羟基吡啶(2,3DHP).在宿主体外进行纯菌和混菌液体培养,3天分别降解含羞草素44—59%,3,4DHP 30—47%和2,3DHP58—60%.经分类鉴定,确定为三个种:BR-1和BR-2很相似,为乳杆菌属(Lactobacillus),可能是一个新种.BR-5为牛链球菌(Streptococcus bovis)和BR-7为生孢梭菌(Clostridiumsporogenes).上述这些兼性和严格厌氧的革兰氏阳性细菌对含羞草素和二羟基吡啶类毒素具有降解活性,这是以前没有报道过的.由于这些脱毒细菌栖居于瘤胃的微生态系统中,从而保护宿主动物免受银合欢的毒害.     

Mimosine arrests the cell cycle prior to the onset of DNA replication by preventing the binding of human Ctf4/And-1 to chromatin via Hif-1α activation in HeLa cells

Though the G₁ checkpoint in mammalian cells has been known for decades, the molecular targets that prevent S-phase entry remain unknown. Mimosine is a rare plant amino acid that arrests the cell cycle in the G₁ phase before entry into S phase. Here, we show that mimosine interrupts the binding of Ctf4 to chromatin, which is essential for the initiation of DNA replication in HeLa cells, and this effect is mediated by the Hif-1α-dependent increase in the level of p27. Depletion of Hif-1α results in an increased binding of Ctf4 to chromatin and the entry of cells into S phase even in the presence of mimosine. These results suggest that the binding of Ctf4 to chromatin is the target of the Hif-1α-dependent checkpoint pathway for cell cycle arrest in G₁ phase. Although we observed Hif-1α-dependent arrest in mimosine-treated cells, it is possible that Ctf4 may act as a common target for G₁ arrest in various other checkpoint pathways.     

Mimosine Mitigates Oxidative Stress in Selenium Deficient Seedlings of <Emphasis Type="Italic">Vigna radiata</Emphasis>-Part I: Restoration of Mitochondrial Function

Mimosine, a non-protein plant amino acid found in Mimosa pudica and certain species of Leucaena, was beneficial for the growth of seedlings of Vigna radiata germinated under selenium-deficient stressed condition (−Se stressed) despite the recognized toxicity of the allelochemical. Exposure of mimosine at 0.1 mM (Mim-0.1) promoted the growth of the seedlings and significantly enhanced mitochondrial functional efficiency. Growth-related parameters including root and shoot lengths and dry weight were increased by 44–58% in the Mim-0.1 group compared to that of the −Se-stressed group. Oxygen uptake by mitochondria of Mim-0.1 group, studied with different substrates, revealed enhanced State 3 respiratory rates with regulated State 4 rates, resulting in high respiratory control ratio (RCR) of 3.4 to 3.9 indicative of a high degree of oxidative coupling. Specific activities of mitochondrial electron transport enzymes, nicotinamide adenine dinucleotide (reduced form) (NADH)–cytochrome (cyt) c oxidoreductase, succinate dehydrogenase, and cyt c oxidase in the Mim-0.1 group were enhanced by 53% to threefold over those of the Se-stressed group. Marked decreases in the extent of mitochondrial lipid peroxidation ensued upon mimosine exposure, indicative of its antioxidant function. Mitochondrial ⁴⁵Ca²⁺ uptake was notably augmented twofold in the Mim-0.1 group, compared to the Se-stressed group. Detailed kinetic analyses of Ca²⁺ uptake revealed positive cooperative interactions in both −Se-stressed group and Mim-0.1 groups with Hill coefficient (nH) values of 1.7 and 2, respectively. The present study establishes the beneficial effects of mimosine exposure at 0.1 mM on the growth and mitochondrial function of the seedlings grown under selenium-deficient stressed condition and a significant physiological role can be ascribed to mimosine.     

The goitrogen 3-hydroxy-4(1H)-pyridone, a ruminal metabolite from Leucaena leucocephala: effects in mice and rats.

Mice fed a diet containing 1% (w/w) 3-hydroxy-4(1H)-pyridone (DHP) developed goitre even with a diet high in iodine whereas mimosine (0.5% w/w) did not produce goitre even with a low-iodine diet. Thyroid enlargement was apparent (measured morphometrically) by the 7th week and was advanced by the 11th week. Histologically the goitre was hyperplastic in type. No marked histological changes were found in other organs of mice fed DHP or any organs of mice fed mimosine, except for some atrophy of hair follicles. A single intragastric dose of DHP inhibited the uptake of 125I by the thyroid in the rat but an equivalent dose of mimosine did not. Evidence is presented that the inhibition occurs at the iodine binding step, as with methyl thiouracil, rather than at the iodide trapping step, as with thiocyanate. Chronic treatment of mice with DHP, as with 6-methyl thiouracil, increased the avidity of the thyroid in taking up 125I. The major conjugated form of DHP in mammals, DHP-3-O-glucuronide, was almost as effective a goitrogen as the unconjugated compound when given by mouth but considerably less active than the free form in the blood stream. It was concluded that DHP is a potent antithyroid compound of the thiouracil type with low general toxicity, since mammals can tolerate a level of intake sufficient to produce goitre in spite of iodine supplementation.     

Cell cycle synchronization of porcine granulosa cells in G1 stage with mimosine

The success of somatic cell nuclear transfer depends critically on the cell cycle stage of the donor nucleus and the recipient cytoplast. Karyoplasts in the G0 or G1 stages are considered to be the most suitable for nuclear transfer. In the present study, we used a reversible cell cycle inhibitor, mimosine, to synchronize porcine granulosa cells (GCs) in G1 phase of the cell cycle. Porcine GCs were obtained from 3 to 5mm ovarian follicles of slaughtered gilts. The effect of mimosine on the proliferation, DNA synthesis and cell cycle stage of cultured cells was examined by incorporation of radiochemical 3H-thymidine, immunocytochemical detection of incorporated thymidine analogue 5-bromo-2-deoxyuridine (BrdU) and flow cytometry analyses. Mimosine treatment of pig GCs for 24h resulted in proliferation arrest in vitro. Treatment with 0.5mM mimosine significantly (P<0.05) inhibited 3H-thymidine incorporation after 24h of culture (4.6% +/- 0.1) and after 24h of culture in serum deprived medium (41.3% +/- 3.8), in comparison to controls (100%). Inhibition of DNA synthesis was further confirmed by immunocytochemical and flow cytometry analyses. Compared with controls (78.2%), mimosine treatment for 24h increased the proportion of G0/G1 cells in the culture (85.7%) more effectively than serum starvation (SS; 81.2%). Mimosine-caused G1 arrest of porcine GCs was fully reversible and cells continued to proliferate after removing the drug, especially when they were stimulated by EGF.     

Preparative scale isolation, purification and derivatization of mimosine, a non-proteinogenic amino acid

Focusing on drug discovery non-proteinogenic amino acids have often been used as important building blocks for construction of compound libraries in the filed of combinatorial chemistry and chemical biology. Highly homogeneous L: -mimosine, α-amino-β-(3-hydoxy-4-oxo-1,4-dihydropyridin-1-yl)-propanoic acid, a non-proteinogenic amino acid, has been successfully isolated and purified on an industrial scale from wild leaves of Leucaena (Leucaena leucocephala de Wit) which is a widely distributed legume in Okinawa, a sub-tropical island in Japan. Optical purity determinations used for quality control have been established through diastereomer formation. Physico-chemical properties and biological properties of purified mimosine have been clarified. Mimosine is sparingly soluble in water and organic solvents but can be dissolved in aqueous alkaline solution. The tyrosinase pathway is of particular interest in the cosmetic field, since mimosine is an analog of tyrosine. Thus the present purified mimosine have been tested in tyrosinase inhibitory assays. The IC50 for tyrosinase inhibitory activity of purified Mim was compared with kojic acid. Mimosine shows significant inhibition of melanin production in murine melanoma cells. The derivatization of mimosine has been investigated with a focus on its use in conventional peptide syntheses to generate mimosyl peptides. N-(9-Fluorenylmethoxycarbonyloxy)-mimosine and resin-bound mimosine for solid-phase syntheses have also been performed. Highly homogeneous Mim is a useful material for the development of functional cosmetics or active pharmaceutical ingredients.