Development of L-Asparaginase Biobetters: Current Research Status and Review of the Desirable Quality Profiles

L-Asparaginase (ASNase) is a vital component of the first line treatment of acute lymphoblastic leukemia (ALL), an aggressive type of blood cancer expected to afflict over 53,000 people worldwide by 2020. More recently, ASNase has also been shown to have potential for preventing metastasis from solid tumors. The ASNase treatment is, however, characterized by a plethora of potential side effects, ranging from immune reactions to severe toxicity. Consequently, in accordance with Quality-by-Design (QbD) principles, ingenious new products tailored to minimize adverse reactions while increasing patient survival have been devised. In the following pages, the reader is invited for a brief discussion on the most recent developments in this field. Firstly, the review presents an outline of the recent improvements on the manufacturing and formulation processes, which can severely influence important aspects of the product quality profile, such as contamination, aggregation and enzymatic activity. Following, the most recent advances in protein engineering applied to the development of biobetter ASNases (i.e., with reduced glutaminase activity, proteolysis resistant and less immunogenic) using techniques such as site-directed mutagenesis, molecular dynamics, PEGylation, PASylation and bioconjugation are discussed. Afterwards, the attention is shifted toward nanomedicine including technologies such as encapsulation and immobilization, which aim at improving ASNase pharmacokinetics. Besides discussing the results of the most innovative and representative academic research, the review provides an overview of the products already available on the market or in the latest stages of development. With this, the review is intended to provide a solid background for the current product development and underpin the discussions on the target quality profile of future ASNase-based pharmaceuticals

Production and immobilization of lipases produced by the endophytic fungus Cercospora kikuchii for biotechnological applications

O objetivo desse trabalho foi avaliar estratégias de imobilização de lipases produzidas pelo fungo endofítico Cercospora kikuchii através do uso de suportes não convencionais (subprodutos agroindustriais e quitosana). Investigou-se o uso de equipamentos de secagem (estufa, leito de jorro, leito fluidizado, liofilizador e \"spray dryer\") para desidratação dos derivados imobilizados obtidos. A imobilização por ligação covalente, usando glutaraldeído, epicloridrina e metaperiodato de sódio como agentes ligantes, apresentou valores para retenção da atividade enzimática superiores à imobilização por adsorção e encapsulação. Nos ensaios de imobilização utilizando glutaraldeído e secagem em leito de jorro, os melhores valores obtidos foram para a celulose microcristalina com retenção da atividade enzimática de 179,1%, seguido da casca de arroz 173,9%. A palha de milho foi o melhor suporte na imobilização covalente e secagem em estufa, com retenção de mais de 100% da atividade enzimática inicial. Na secagem por liofilização houve destaque para a casca de arroz (163,6%) seguida de palha de milho (157,2%) e cana de açúcar (154,6%). Utilizando quitosana como suporte e secagem em leito fluidizado, o valor para a retenção da atividade enzimática foi de 93,9% empregando-se o glutaraldeído como agente ligante. Na secagem do sistema quitosana-lipase em estufa a retenção da atividade enzimática foi de 68,2% e para secagem por liofilização esse valor foi superior a 80,0%. Realizou-se a caracterização dos materiais utilizados como suportes e estes apresentaram área superficial relativamente alta, elevada porosidade e estrutura constituída de macroporos. Estas características foram importantes por proporcionar a obtenção da enzima imobilizada com alta retenção da atividade catalítica. Alguns parâmetros bioquímicos e cinéticos da lipase na forma livre foram diferentes da lipase imobilizada. A alteração mais evidente foi a afinidade ao substrato (Km), que se mostrou dependente do protocolo de imobilização utilizado. Avaliou-se o potencial de aplicação biotecnológica dos derivados imobilizados que apresentaram maior retenção da atividade enzimática. Para a lipase imobilizada em casca de arroz o rendimento de transesterificação (produção de biodiesel) foi superior a 96,0% após 72 horas de reação enquanto que para as microesferas de quitosana esse valor foi atingido após 120 horas. Os produtos obtidos da transesterificação do óleo de coco estão de acordo com a especificação da Agência Nacional de Petróleo (ANP). Na avaliação da atividade de esterificação, a máxima concentração de butirato de butila foi obtida após 6 horas de reação, correspondendo a uma taxa de conversão de aproximadamente 99,0%, quando utilizou-se quitosana como suporte. Para o uso da casca de arroz, a máxima concentração de butirato de butila foi obtida também após 6 horas de reação, correspondendo a uma taxa de conversão de 92,5%. Este trabalho demonstrou que suportes de baixo custo permitiram a obtenção de derivados imobilizados com características semelhantes àqueles obtidos com o uso de polímeros sintéticos, os quais apresentaram excelente potencial para síntese de biodiesel e de butirato butila.The objective of this study was to evaluate strategies for immobilization of lipases produced by the endophytic fungus Cercospora kikuchii through the use of unconventional supports (agroindustrial by-products and chitosan). The use of different drying process (oven, spouted bed, fluidized bed, freeze drying and spray drying) for dehydration of immobilized derivatives obtained by adsorption, covalent binding and encapsulation was investigated. The covalent immobilization (using glutaraldehyde, epichlorohydrin and sodium metaperiodate as crosslinking agents) was the best process for the enzymatic activity retention. For covalent immobilization using glutaraldehyde and spouted bed drying, the best values were obtained for microcrystalline cellulose with enzymatic activity retention of 179.1%, followed by rice husk and corn straw with 173.9% and 169.8%, respectively. Corn stover was the best support in the covalent immobilization and oven drying, with retention 100.0% of the initial enzyme activity. For freeze-drying rice husk was the best support (163.6%) followed by corn stover (157.2%), sugar cane bagasse (154.6%) and corn cob (129.5%). Utilizing chitosan as support and fluidized bed drying, the value for the retention of enzymatic activity was 93.9% employing glutaraldehyde as activating agent. For chitosan-lipase drying using oven, the enzymatic activity retention was 68.2% and using freeze-drying the retention of enzymatic activity was higher than 80.0%. The support characterization was carried out and showed high surface area, high porosity and macropore structure. These characteristics were important for providing immobilized derivatives with high catalytic activity retention. Some biochemical and kinetic parameters of lipase in free form were different from the immobilized lipase. The most important changes was the substrate affinity (Km) which was dependent of immobilization protocol used. The last experimental part of this study was the biotechnological applications of the best immobilized derivatives produced. For the immobilized lipase onto rice husk the transesterification yield (biodiesel production) was above 96.0% after 72 hours of reaction while for the use of chitosan microspheres this value was reached after 120 hours. The viscosity values for the biodiesel samples are in accordance with specifications recommended by Brazilian Petroleum Agency (ANP) to be used as biofuel. The immobilized derivatives catalytic power was measured in terms of esterification activity too. The maximum concentration for butyl butyrate was obtained after 6 hours, corresponding to conversion rate of 99.0% when chitosan was used as support. Using rice husk, the maximum butyl butyrate concentration was obtained after 6 hours of reaction, corresponding to conversion rate of 92.5%. This work demonstrated that cheap supports are biocompatible with lipases, rendering immobilized derivatives with characteristics similar to or better than those previously obtained with synthetic polymers. The immobilized derivatives showed excelente potential for biodiesel production and butyl butyrate synthesis

Biochemical characterization and spray drying of lipases produced by the endophytic fungus Cercospora kicuchii.

Lipases são enzimas que catalisam a hidrólise de triacilgliceróis em ácidos graxos, mono e diacilgliceróis e glicerol. Em contraste com as esterases, lipases são ativadas apenas quando estão adsorvidas a uma interface óleo-água. Lipases têm sido amplamente utilizadas em muitos processos industriais, tais como química orgânica, formulações de detergentes e de produtos como cosméticos e farmacêuticos. A principal preocupação na produção de enzimas comerciais é a proteção da sua estabilidade em solução aquosa. A água facilita ou medeia uma variedade de vias de degradação física e química, durante as etapas de purificação, transporte e armazenamento. Por conseguinte, formulações sólidas são desenvolvidas para alcançar uma vida útil aceitável para essas substâncias. Spray drying é comumente usado como uma técnica de desidratação na indústria farmacêutica para fabricação de produtos em pó diretamente do estado líquido. No presente trabalho, a purificação e caracterização bioquímica de lipases produzidas pelo fungo endofítico Cercospora kikuchii, bem como os efeitos de adjuvantes no processo de secagem destas enzimas foram estudados. A lipase bruta foi purificada à homogeneidade através de cromatografia de interação hidrofóbica e gel filtração. A lipase foi purificada 5,54 vezes, com rendimento de 9% e a atividade específica de 223,6 U/mg. O peso molecular da enzima foi estimado em 65,1 kDa por SDS-PAGE e 73,5 kDa utilizando cromatografia de gel filtração, indicando que provavelmente trata-se de um monômero. A lipase mostrou um pH ótimo em 4,6 e uma temperatura ótima de 35°C. Cerca de 80,2% de sua atividade foi mantida após incubação a 40°C durante 2 horas. A Vmax e Km foram 10,28 mmol/min/mg de proteína e 0,03240 mM, respectivamente, utilizando pNPP como substrato. As lipases presentes no extrato bruto e as lipases ligadas ao micélio foram caracterizadas para avaliar o potencial de utilização em biocatálise. A lipases no extrato bruto apresentaram atividade máxima a 60ºC e pH 6,2, enquanto que as lipases ligadas ao micélio apresentaram atividade máxima a 50ºC e pH 5,4. Nos estudos de efeito da temperatura sobre a atividade enzimática, as lipases no extrato bruto mantiveram-se estáveis a 50°C, com 85,3% de atividade residual após 2 horas de incubação. As lipases ligadas ao micélio mantiveram pelo menos 75,1% de atividade residual após 2 horas de incubação a 80°C. Estes resultados mostram que as lipases de C. kikuchii têm propriedades cinéticas e termoestabilidade desejáveis para aplicações em biocatálise. As lipases presentes no extrato bruto foram secas em spray dryer com diferentes adjuvantes, e sua estabilidade foi avaliada. A recuperação da atividade enzimática após a secagem, com a adição de 10% de lactose, -ciclodextrina, maltodextrina, manitol, goma arábica, e trealose variou de 63 a 100%. A atividade da enzima foi totalmente perdida durante a secagem do extrato bruto na ausência de adjuvantes. A maioria dos adjuvantes utilizados manteve pelo menos 50% da atividade enzimática a 5°C e 40% a 25°C, após 8 meses de armazenagem. As lipases secas com 10% de - ciclodextrina mantiveram 72% da atividade a 5°C no mesmo período. A partir destes resultados preliminares foi realizada a otimização do processo de secagem utilizando -ciclodextrina, maltodextrina e lactose como adjuvantes. A análise estatística dos resultados experimentais permitiu a determinação das condições ótimas para a retenção da atividade enzimática (RAE), a saber: concentração de adjuvantes de secagem de 12,05%, temperatura de entrada do gás de secagem em 153,6oC e vazão do extrato enzimático alimentado de 9,36 g/min, para - ciclodextrina e maltodextrina como adjuvantes. Para lactose, o estudo mostrou que o aumento da quantidade de adjuvante de secagem e/ou diminuindo a temperatura do gás de entrada tem um efeito positivo sobre a retenção da atividade enzimática do produto seco. Após o processo de purificação foi realizada a secagem da enzima parcialmente purificada e da lipase pura, com estes três adjuvantes. A manutenção da atividade enzimática variou 90,6-100% quando foram utilizadas as condições ótimas para cada adjuvante de secagem. Concluindo, as lipases produzidas por C. kikuchii podem ser eficientemente secas por spray dryer, uma vez que a atividade enzimática foi mantida no extrato bruto, na lipase pura e na lipase semi-purificada submetidas à secagem.Lipases are enzymes that catalyze the hydrolysis of triacylglycerols to fatty acids, mono and diacylglycerols, and glycerol. In contrast to esterases, lipases are activated only when they are adsorbed to an oilwater interface. They have been widely used in many industrial processes such as organic chemical, detergent and cleaning formulations and in products like cosmetics and pharmaceutical products. The main concern in the production of commercial enzymes is to protect their stability in aqueous solution. Water facilitates or mediates a variety of physical and chemical degradation pathways, active during protein purification, shipping and storage. Consequently, dry solid formulations are developed to achieve an acceptable protein shelf life. Spray drying is commonly used as a dehydration technique in the pharmaceutical industry for making powdery products directly from the liquid. In the present work, the purification and biochemical characterization of lipases produced by endophytic fungus Cercospora kikuchii as well as the effects of adjuvants on the spray drying process of theses enzymes were studied. The crude lipase was purified to homogeneity by hydrophobic interaction chromatography and gel filtration. The lipase purified was 5.54-fold with 9% recovery and the specific activity was 223.6. The molecular mass of the lipase was estimated to be 65.1 kDa using SDS-PAGE and 73.5 using gel filtration chromatography, indicating that the lipase is a monomer. The lipase demonstrated an optimum pH at 4.6, an optimum temperature of 35°C. About 80.2% of its activity was retained after incubation at 40°C for 2 hours. The Vmax and Km were 10.28 mol/min/mg protein and 0.03240 mM, respectively, using pNPP as substrate. The lipases present in crude extract and the mycelium-bound lipases were characterized in order to evaluate the potential for use in biocatalysis. The crude extract showed maximum activity at 60ºC and pH 6.2 while the myceliumbound lipases showed maximum activity at 50ºC and pH 5.4. In tests of the temperature effect on the enzymatic activity, the lipases in the crude extract was stable at 50°C, with 85.3% residual activity after 2 hours of incubation. The mycelium-bound lipases maintained at least 75.1% of residual activity after 2 h incubation at 80°C. These results show that the lipases of C. kikuchii have kinetic properties and stability characteristics suitable to applications in biocatalysis. The lipases present in crude extract were spray dried with different adjuvants, and their stability was evaluated. The recovery of the enzyme after drying with 10% of lactose, -cyclodextrin, maltodextrin, mannitol, gum arabic, and trehalose ranged from 63% to 100%; but the enzyme activity was lost in the absence of adjuvants. Most of the adjuvants used kept up at least 50% of the enzymatic activity at 5°C and 40% at 25°C after 8 months. The lipase dried with 10% of -cyclodextrin retained 72% of activity at 5°C. From these preliminary results the optimization of drying process using -cyclodextrin, maltodextrin and lactose as adjuvants was carried out. Statistical optimization of the experimental results allowed the determination of the processing conditions that maximized the retention of the enzymatic activity (RAE), namely: concentration of drying adjuvants of 12.05 %, inlet temperature of the drying gas of 153.6oC, and flow rate of the enzymatic extract fed to the dryer of 9.36 g/min, for the b-cyclodextrin and maltodextrin as adjuvants. For lactose as adjuvant the study showed that increasing the amount of drying adjuvant and/or decreasing the inlet gas temperature has positive effect on the retention of enzymatic activity of the dried product. After the purification process was carried out the drying of the partially purified enzyme and pure lipase, using these three adjuvants. The retention of enzymatic activity ranged from 90.6 to 100% when was used the optimal conditions for each drying adjuvant. Concluding, the lipases produced by C. kikuchii may be efficiently spray dried since its activity enzimatic was retained in crude extract, pure lipase and in semi-purified lipase after drying

Immobilization of Lipases Produced by the Endophytic Fungus Cercospora kikuchii on Chitosan Microparticles

This work studied the immobilization of Cercospora kikuchii lipases on chitosan microparticles by chemical attachment on chitosan acetate microparticles activated by glutaraldehyde (CAM) added before or after the enzyme and physical adsorption on highly deacetylated chitosan hydrochloride microparticles (CHM). Lipases covalently immobilized on pre-activated CAM showed better performance retaining 88.4% of the enzymatic activity, with 68.2% of immobilization efficiency (IE). The immobilized enzyme retained an activity of about 53.5 % after five reuses, using p-NPP as substrate. Physical adsorption of lipase onto highly deacetylated CHM showed 46.2 % of enzymatic activity and 28.6% of IE. This immobilized derivative did not lose activity up to 80 days of storage at 4°C, while lipases immobilized on pre-activated CAM maintained its activity up to 180 days at same conditions. Taken together the results indicate that chitosan microparticles provide an optimal microenvironment for the immobilized enzyme to maintain good activity and stability

Anticancer Asparaginases: Perspectives in Using Filamentous Fungi as Cell Factories

The enzyme L-asparaginase (L-asparagine amidohydrolase) catalyzes the breakdown of L-asparagine into aspartate and ammonia, which leads to an anti-neoplastic activity stemming from its capacity to deplete L-asparagine concentrations in the bloodstream, and it is therefore used in cases of acute lymphoblastic leukemia (ALL) to inhibit malignant cell growth. Nowadays, this anti-cancer enzyme, largely produced by Escherichia coli, is well established on the market. However, E. coli L-asparaginase therapy has side effects such as anaphylaxis, coagulation abnormality, low plasma half-life, hepatotoxicity, pancreatitis, protease action, hyperglycemia, and cerebral dysfunction. This review provides a perspective on the use of filamentous fungi as alternative cell factories for L-asparaginase production. Filamentous fungi, such as various Aspergillus species, have superior protein secretion capacity compared to yeast and bacteria and studies show their potential for the future production of proteins with humanized N-linked glycans. This article explores the past and present applications of this important enzyme and discusses the prospects for using filamentous fungi to produce safe eukaryotic asparaginases with high production yields

Genotoxicity of Nicotiana tabacum leaves on Helix aspersa

Tobacco farmers are routinely exposed to complex mixtures of inorganic and organic chemicals present in tobacco leaves. In this study, we examined the genotoxicity of tobacco leaves in the snail Helix aspersa as a measure of the risk to human health. DNA damage was evaluated using the micronucleus test and the Comet assay and the concentration of cytochrome P450 enzymes was estimated. Two groups of snails were studied: one fed on tobacco leaves and one fed on lettuce (Lactuca sativa L) leaves (control group). All of the snails received leaves (tobacco and lettuce leaves were the only food provided) and water ad libitum. Hemolymph cells were collected after 0, 24, 48 and 72 h. The Comet assay and micronucleus test showed that exposure to tobacco leaves for different periods of time caused significant DNA damage. Inhibition of cytochrome P450 enzymes occurred only in the tobacco group. Chemical analysis indicated the presence of the alkaloid nicotine, coumarins, saponins, flavonoids and various metals. These results show that tobacco leaves are genotoxic in H. aspersa and inhibit cytochrome P450 activity, probably through the action of the complex chemical mixture present in the plant

Genotoxicity of Nicotiana tabacum leaves on Helix aspersa

Tobacco farmers are routinely exposed to complex mixtures of inorganic and organic chemicals present in tobacco leaves. In this study, we examined the genotoxicity of tobacco leaves in the snail Helix aspersa as a measure of the risk to human health. DNA damage was evaluated using the micronucleus test and the Comet assay and the concentration of cytochrome P450 enzymes was estimated. Two groups of snails were studied: one fed on tobacco leaves and one fed on lettuce (Lactuca sativa L) leaves (control group). All of the snails received leaves (tobacco and lettuce leaves were the only food provided) and water ad libitum. Hemolymph cells were collected after 0, 24, 48 and 72 h. The Comet assay and micronucleus test showed that exposure to tobacco leaves for different periods of time caused significant DNA damage. Inhibition of cytochrome P450 enzymes occurred only in the tobacco group. Chemical analysis indicated the presence of the alkaloid nicotine, coumarins, saponins, flavonoids and various metals. These results show that tobacco leaves are genotoxic in H. aspersa and inhibit cytochrome P450 activity, probably through the action of the complex chemical mixture present in the plant