Antiproliferative Activity on Human Colon Adenocarcinoma Cells and In Vitro Antioxidant Effect of Anthocyanin-Rich Extracts from Peels of Species of the Myrtaceae Family.

There is a significant indication of the beneficial health effects of fruit rich diets. Fruits of native plant species have noticeably different phytochemicals and bioactive effects. The aim of this work was to characterize and compare the constituents of jabuticaba (Myrciaria jaboticaba, MJ), jamun-berry (Syzygium cumini, SC), and malay-apple (Syzygium malaccense, SM) extracts and their influence on antioxidant activity in vitro and antiproliferative effects on human colon adenocarcinoma cells. According to the results, dried peel powders (DP) have a high anthocyanin content, phenolic compounds, and antioxidant activity when compared to freeze dried extracts (FD). M. jaboticaba dried peel powder extract had a higher total anthocyanin and phenolic compounds content (802.90 ± 1.93 and 2152.92 ± 43.95 mg/100 g, respectively). A reduction in cell viability of HT-29 cells after treatment with M. jaboticaba extracts (DP-MJ and FD-MJ) was observed via MTT assay. Flow cytometry showed that the treatment with the anthocyanin-rich extracts from MJ, SC, and SM had an inhibitory impact on cell development due to G2/M arrest and caused a rise in apoptotic cells in relation to the control group. The findings of this study highlight the potential of peel powders from Myrtaceae fruits as an important source of natural antioxidants and a protective effect against colon adenocarcinoma.

Syzygium cumini (L.) skeels: a prominent source of bioactive molecules against cardiometabolic diseases.

Syzygium cumini (Myrtaceae) is a worldwide medicinal plant traditionally used in herbal medicines due to its vaunted properties against cardiometabolic disorders, which include: antihyperglycemic, hypolipemiant, antiinflammatory, cardioprotective, and antioxidant activities. These properties have been attributed to the presence of bioactive compounds such as phenols, flavonoids, and tannins in different parts of the plant, albeit the knowledge on their mechanisms of action is scarce. This mini-review highlights the cardiometabolic properties of S. cumini by correlating its already identified phytochemicals with their described mechanisms of action. Data herein compiled show that some compounds target multiple metabolic pathways; thereby, becoming potential pharmacological tools. Moreover, the lack of clinical trials on S. cumini usage makes it a fruitful field of interest for both scientific community and pharmaceutical industry.

Optimization of culture conditions for tannase production by Aspergillus sp. gm4 in solid state fermentation / Otimização das condições de cultivo para produção de tanase por Aspergillus sp. gm4 em fermentação em estado sólido

Tannase is an industrially important enzyme produced by a large number of microorganisms. This study analyzed the production of tannase by Aspergillus sp. GM4 under solid-state fermentation (SSF) using different vegetable leaves (mango, jamun and coffee) and agricultural residues (coffee husks, rice husks and wheat bran). Among the substrates used jamun leaves yielded high tannase production. The Plackett-Burman design was conducted to evaluate the effects of 12 independent variables on the production of tannase under SSF using jamun leaves as substrate. Among these variables, incubation time, potassium nitrate and tannic acid had significant effects on enzyme production. A lower incubation time was fixed and supplementation with potassium nitrate and tannic acid were optimized using the Central Composite Design. The best conditions for tannase production were: incubation time of 2 days; tannic acid at 1.53% (w w-1) and potassium nitrate at 2.71% (w w- 1). After the optimization process, tannase production increased 4.65-fold, which showed that the statistical experimental design offers a practicable approach to the implementation of optimization of tannase production.

Tanase é uma enzima industrialmente importante produzida por um grande número de microrganismos. Este estudo analisou a produção de tanase por Aspergillus sp. GM4 em fermentação em estado sólido (FES) utilizando diferentes vegetais como folhas de manga, de jambolão, de café e resíduos agrícolas, como a casca de café, casca de arroz e farelo de trigo. Entre os substratos utilizados, as folhas jambolão renderam alta produção de tanase. O planejamento de Plackett-Burman foi conduzido para avaliar os efeitos de 12 variáveis independentes sobre a produção de tanase em FES usando folhas jambolão como substrato. Entre estas variáveis, tiveram efeitos significativos na produção da enzima o tempo de incubação, o nitrato de potássio e o ácido tânico. O menor tempo de incubação foi fixado e a suplementação de nitrato de potássio e ácido tânico foi otimizada utilizando o planejamento composto central rotacional. As melhores condições para a produção de tanase foram o tempo de incubação de dois dias, a concentração de ácido tânico de 1,53% (g g-1) e de nitrato de potássio 2,71% (g gw-1). Após o processo de otimização, a produção tanase aumentou 4,65 vezes, o que mostrou que o delineamento experimental foi um método viável para a otimização da produção de tanase.

Otimização das condições de cultivo para produção de tanase por Aspergillus sp. gm4 em fermentação em estado sólido / Optimization of culture conditions for tannase production by Aspergillus sp. gm4 in solid state fermentation

Tanase é uma enzima industrialmente importante produzida por um grande número de microrganismos. Este estudo analisou a produção de tanase por Aspergillus sp. GM4 em fermentação em estado sólido (FES) utilizando diferentes vegetais como folhas de manga, de jambolão, de café e resíduos agrícolas, como a casca de café, casca de arroz e farelo de trigo. Entre os substratos utilizados, as folhas jambolão renderam alta produção de tanase. O planejamento de Plackett-Burman foi conduzido para avaliar os efeitos de 12 variáveis independentes sobre a produção de tanase em FES usando folhas jambolão como substrato. Entre estas variáveis, tiveram efeitos significativos na produção da enzima o tempo de incubação, o nitrato de potássio e o ácido tânico. O menor tempo de incubação foi fixado e a suplementação de nitrato de potássio e ácido tânico foi otimizada utilizando o planejamento composto central rotacional. As melhores condições para a produção de tanase foram o tempo de incubação de dois dias, a concentração de ácido tânico de 1,53% (g g-1) e de nitrato de potássio 2,71% (g gw-1). Após o processo de otimização, a produção tanase aumentou 4,65 vezes, o que mostrou que o delineamento experimental foi um método viável para a otimização da produção de tanase.(AU)

Tannase is an industrially important enzyme produced by a large number of microorganisms. This study analyzed the production of tannase by Aspergillus sp. GM4 under solid-state fermentation (SSF) using different vegetable leaves (mango, jamun and coffee) and agricultural residues (coffee husks, rice husks and wheat bran). Among the substrates used jamun leaves yielded high tannase production. The Plackett-Burman design was conducted to evaluate the effects of 12 independent variables on the production of tannase under SSF using jamun leaves as substrate. Among these variables, incubation time, potassium nitrate and tannic acid had significant effects on enzyme production. A lower incubation time was fixed and supplementation with potassium nitrate and tannic acid were optimized using the Central Composite Design. The best conditions for tannase production were: incubation time of 2 days; tannic acid at 1.53% (w w-1) and potassium nitrate at 2.71% (w w-1). After the optimization process, tannase production increased 4.65-fold, which showed that the statistical experimental design offers a practicable approach to the implementation of optimization of tannase production.(AU)

Tannase production by Penicillium atramentosum KM under SSF and its applications in wine clarification and tea cream solubilization

Tannin acyl hydrolase commonly known as tannase is an industrially important enzyme having a wide range of applications, so there is always a scope for novel tannase with better characteristics. A newly isolated tannase-yielding fungal strain identified as Penicillium atramentosum KM was used for tannase production under solid-state fermentation (SSF) using different agro residues like amla (Phyllanthus emblica), ber (Zyzyphus mauritiana), jamun (Syzygium cumini), Jamoa (Eugenia cuspidate) and keekar (Acacia nilotica) leaves. Among these substrates, maximal extracellular tannase production i.e. 170.75 U/gds and 165.56 U/gds was obtained with jamun and keekar leaves respectively at 28ºC after 96 h. A substrate to distilled water ratio of 1:2 (w/v) was found to be the best for tannase production. Supplementation of sodium nitrate (NaNO3) as nitrogen source had enhanced tannase production both in jamun and keekar leaves. Applications of the enzyme were studied in wine clarification and tea cream solubilization. It resulted in 38.05 percent reduction of tannic acid content in case of jamun wine, 43.59 percent reduction in case of grape wine and 74 percent reduction in the tea extract after 3 h at 35ºC.

Tannase Production by Penicillium Atramentosum KM under SSF and its Applications in Wine Clarification and Tea Cream Solubilization.

Tannin acyl hydrolase commonly known as tannase is an industrially important enzyme having a wide range of applications, so there is always a scope for novel tannase with better characteristics. A newly isolated tannase-yielding fungal strain identified as Penicillium atramentosum KM was used for tannase production under solid-state fermentation (SSF) using different agro residues like amla (Phyllanthus emblica), ber (Zyzyphus mauritiana), jamun (Syzygium cumini), Jamoa (Eugenia cuspidate) and keekar (Acacia nilotica) leaves. Among these substrates, maximal extracellular tannase production i.e. 170.75 U/gds and 165.56 U/gds was obtained with jamun and keekar leaves respectively at 28ºC after 96 h. A substrate to distilled water ratio of 1:2 (w/v) was found to be the best for tannase production. Supplementation of sodium nitrate (NaNO3) as nitrogen source had enhanced tannase production both in jamun and keekar leaves. Applications of the enzyme were studied in wine clarification and tea cream solubilization. It resulted in 38.05% reduction of tannic acid content in case of jamun wine, 43.59% reduction in case of grape wine and 74% reduction in the tea extract after 3 h at 35°C.

Tannase production by Penicillium atramentosum KM under SSF and its applications in wine clarification and tea cream solubilization

Tannin acyl hydrolase commonly known as tannase is an industrially important enzyme having a wide range of applications, so there is always a scope for novel tannase with better characteristics. A newly isolated tannase-yielding fungal strain identified as Penicillium atramentosum KM was used for tannase production under solid-state fermentation (SSF) using different agro residues like amla (Phyllanthus emblica), ber (Zyzyphus mauritiana), jamun (Syzygium cumini), Jamoa (Eugenia cuspidate) and keekar (Acacia nilotica) leaves. Among these substrates, maximal extracellular tannase production i.e. 170.75 U/gds and 165.56 U/gds was obtained with jamun and keekar leaves respectively at 28ºC after 96 h. A substrate to distilled water ratio of 1:2 (w/v) was found to be the best for tannase production. Supplementation of sodium nitrate (NaNO3) as nitrogen source had enhanced tannase production both in jamun and keekar leaves. Applications of the enzyme were studied in wine clarification and tea cream solubilization. It resulted in 38.05% reduction of tannic acid content in case of jamun wine, 43.59% reduction in case of grape wine and 74% reduction in the tea extract after 3 h at 35ºC.