EXCLI J EXCLI Journal 1611-2156 Leibniz Research Centre for Working Environment and Human Factors 2017-218 10.17179/excli2017-218 Doc840 Original article High carotenoid production by a halotolerant bacterium, Kocuria sp. strain QWT-12 and anticancer activity of its carotenoid Rezaeeyan Zahra 1 Safarpour Atefeh 2 Amoozegar Mohammad Ali * 1 Babavalian Hamid 3 Tebyanian Hamid 4 5 Shakeri Fatemeh 4 Extremophiles Laboratory, Department of Microbiology, Faculty of Biology and Center of Excellence in Phylogeny of Living Organisms, College of Science, University of Tehran, Tehran, Iran Department of Stem Cells and Developmental Biology, Cell Science Research Center, Royan Institute for Stem Cell Biology and Technology, ACECR, Tehran 19395-4644, Iran Applied Virology Research Center, Baqiyatallah University of Medical Sciences, Tehran, Iran Division of Tissue Engineering and Regenerative Medicine, Nanobiotechnology Research Center, Baqiyatallah University of Medical Sciences, Tehran, Iran Research Center for Prevention of Oral and Dental Disease, Baqiyatallah University of Medical Sciences, Tehran, Iran *To whom correspondence should be addressed: Mohammad Ali Amoozegar, Extremophiles Laboratory, Department of Microbiology, Faculty of Biology and Center of Excellence in Phylogeny of Living Organisms, College of Science, University of Tehran, Tehran, Iran, Telephone: +98 21 61113557, Fax: +98 21 23562507, E-mail: amoozegar@ut.ac.ir 12 06 2017 2017 16 840 851 16 02 2017 30 03 2017 Copyright © 2017 Rezaeeyan et al. 2017

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Halophilic prokaryotes are extremophile microorganisms that grow optimally in media containing salts and almost appeared pigmented. Many of them contain high concentrations of carotenoids. Amongst 15 strains of halophilic prokaryotes isolated from industrial tannery wastewater in Qom, a Gram-stain-positive coccoid, aerobic, non-endospore-forming, halotolerant bacterium designated as strain QWT-12 showed high capacity in the production of carotenoids in a wide range of culture medium factors. 16S rRNA gene analysis showed that this strain belongs to the genus Kocuria. Carotenoids from this strain were extracted by methanol. MTT assay for extracted carotenoid was carried out against seven cancer cell lines belonging to breast, lung and prostate cancer with negative control of fibroblast cell line through six concentration levels to find out IC50. Based on statistical analysis of data from MTT assay, IC50 of 1, 4 and 8 mg/ml for MCF-7, (A549 and MDA-MB-468) and MDA-MB-231 respectively. Additionally, qualitative carotenoid determination was carried out using spectrophotometric method in 300-600 nm and thin layer chromatography, respectively. According to the obtained results from mass spectrophotometry, absorption spectrum of strain QWT-12 is similar to the absorption spectrum of the carotenoid neurosporene.

halotolerant bacteria Kocuria yellow pigmented bacteria carotenoid cancer cell line
Introduction

Carotenoids are yellow to orange-red pigments widely distributed among nature of many organisms. Their existence happens from bacteria, yeast and algae to animal and plant cells (Basu et al., 2001[3]). Animals are unable to produce carotenoids naturally and presence of carotenoids in their cells is due to their diets which include plant carotenoids (Mortensen, 2006[17]). There are two types of carotenoids structurally, carotenes and xanthophylls. Carotenes group are hydrocarbons without any oxygen atoms while xanthophylls are oxygenated hydrocarbons (de Quirós and Costa, 2006[6]). Almost more than 700 chemical compounds have been classified as carotenoids while about 500 of them have been structurally elucidated. These diverse chemical structures increased functional capability of carotenoids for various biological applications since the exact chemical structure of individual carotenoids is decisive for expected properties and also it determines how they interact with other molecules (Konishi et al., 2008[11]; Irwandi et al., 2011[10]). In addition to antioxidant activity, other applications of carotenoids have been studied as absorbers of light and energy, oxygen transporters, provitamin A, scavengers of active oxygen, antitumor and enhancers of in vitro antibody production (Britton et al., 2009[4]). Some of the carotenoids are used commercially as nutritional supplements (lutein), pharmaceuticals (beta-carotene), and food colorants (canthaxanthin) for humans and also as pigments for animal feed (Gordon and Bauernfeind, 1982[9]; Britton et al., 2009[4]). In this competition, new organism producers, innovative processes and well-mixed carotenoid extracts are highly demanded for food nutrition industries (Britton et al., 2009[4]). Additionally, regarding to new reports from medicinal chemists, it has been shown that complex of several discovered carotenoids can have prevention effects against many diseases (Labi et al., 2008[12]) and among them, cancer chemoprevention has been considered the most important part of preclinical investigations that carotenoids showed great functionality to be used in. Diverse carotenoids like β-carotene, lycopene, β-cryptoxanthin, lutein, zeaxanthin, fucoxanthin, canthaxanthin and astaxanthin have been reported to exhibit anticancer effect in both in vitro and in vivo studies (Tanaka et al., 2012[29]). Many of halotolerant and halophilic microorganisms contain high concentrations of various carotenoids and usually saltern ponds are colored place due to the presence of pigmented microorganisms such as Dunaliella which mainly produce β-carotene, haloarchaeal bacterioruberins and some halophilic bacteria such as Salinibacter genus that produce salinixanthin carotenoid (Moreno et al., 2012[5]). With the rising global concern to avoid the undesirable effects of synthetic food colorants such as allergy, hypersensitivity, intolerance and childhood hyperactivity (Nguyen, 2013[19]), in this study, we screened halotolerant bacterial strains isolated from tannery wastewater of a company in Qom city in center of Iran, for carotenoid production while effects of different parameters on bacterial growth and carotenoids production of positive ones are also evaluated. MTT assay was done to find the anticancer activity of extracted pigments and then the type of extracted pigments estimated by Thin Layer Chromatography (TLC) and Mass Spectrophotometry (MS).

Materials and MethodsMaterials

All the materials and reagents for bacterial cultures and TLC, were purchased from Merck (E. Merck, Darmstadt, Germany).

Isolation, media and culture collections

Water samples were obtained from tannery wastewater of a company in Qom, Iran. Approximately 1 ml of each sample was poured in 20 ml of nutrient broth medium with 20 % solar salt. The pH was adjusted to 7.2. The flasks were incubated on a shaker at 37 °C until turbidity appeared. The turbid cultures were streaked on nutrient agar 20 % with solar salt and incubated at 37 °C. After 14 day of incubation, yellow colonies were selected and purified (Asker and Ohta, 1999[2]). Amongst 15 isolated halophilic strains, QWT-12, a bacterial strain with sharp yellow colonies were selected for further experiments. Salt tolerance assays for QWT-12 strain were performed by growing it in nutrient broth plus various concentrations of NaCl (0 to 15 % w/v) at 37 °C. The bacterial growth was monitored at temperature range of 10-50 °C with intervals of 5 °C and over a pH values range from 5.0 to 10.0. Sodium acetate buffer was used for pH 6 and lower while Tris-HCl buffer was used for pH higher than 6.

Identification of the strain

Morphological and physiological characteristics of the strain were either studied on nutrient agar or in nutrient broth plus 3 % (w/v) NaCl. Gram reaction, shape and color of colony, catalase, indole formation and oxidase activities, nitrate reduction and tween 80 hydrolyses were checked as recommended by Smibert and Krieg (1994[27]). Carbon and nitrogen sources utilization were performed according to Ventosa et al. (1982[31]).

Genomic DNA from strain QWT-12 was prepared using the method described by Marmur (1961[14]). The 16S rRNA gene was amplified by PCR with the forward primer 16F27 and the reverse primer 16R1488 as described by Mellado et al. (1995[16]). Direct sequence determination of the amplified DNA was carried out using an automated DNA sequencer (ABI 3130 XL; Applied Biosystems) at the SeqLab Laboratory (Göttingen, Germany). The 16S rRNA molecule phylogenetic analysis was performed using the software package MEGA version 5 (Tamura et al., 2011[28]) after obtaining multiple alignments of data available from public databases (Thompson et al., 1997[30]). Clustering was performed using the neighbour-joining (Saitou and Nei, 1987[25]), maximum-parsimony and minimum-evolution methods. Bootstrap analysis was used to evaluate the tree topology of the neighbour-joining data by performing 1000 resamplings (Felsenstein, 1985[7]).

Carotenoid production and extraction

Five culture media including TSB, NB, HM, SW and MH mediums were used to find the proper medium for pigment production. The cells were grown at 37 ºC for 24 hours in each medium. After evaluation of optical density and optical pigmentation, TSB medium culture was selected as proper medium to optimize carotenoid production. Additionally, gradient of NaCl, NaNO3, Na2SO4 and KCl in TSB medium were also evaluated to optimize cell growth and pigmentation. Growth curve of strain QWT-12 was drawn in rational to OD and cell pigmentation to find proper time point for pigment extraction.

In order to pigment extraction, the yellow pigmented bacterial isolates were grown in TSB with 3 % (w/v) of salt, in a rotary shaker at 180 rpm in 37 °C for three days. After three days, cells were harvested by centrifugation at 8,000 g for 15 min. Then the pellet was washed with sterile distilled water and spin for 15 min at 4,000 g. Five ml of methanol was added to the pellet and suspended it. Then it was incubated in a water bath at 60 °C for 15 min until all visible pigments were extracted and centrifuged at 4,000 g for 15 min. The colored supernatant was separated, then it was filtered through Whatman no. 1 filter paper. The carotenoid extracts were analyzed by scanning the absorbance in the wavelength region of 450 nm using the spectrophotometer. The total carotenoid content in the methanol extract was estimated by measuring the absorbance at λmax (450 nm) (Ravindar et al., 2014[23]). For MTT assay after evaporating of methanol, the carotenoids were dissolved in ethanol (Abbes et al., 2013[1]).

Human cell culture

Human cancer cell lines that were used in this project were DU145, PC3, LNCaP for prostate cancer and MDA-MB-468, MDA-MB-231, MCF-7 for breast cancer and A549 for lung cancer. As control cell line we used human skin fibroblast cell line Hu02. All cell lines were purchased from IBRC Cell bank. The cells were grown as a monolayer in an RPMI 1640 medium (Gibco) supplemented with 10 % (v/v) fetal bovine serum (FBS) (Gibco), 1.0 mM sodium pyruvate (Sigma) and 2 mM L-glutamine (Sigma) at 37 °C in a humidified atmosphere of 95 % air and 5 % CO2. After 24 h of growth, the cells were transferred into a 96-well plate (2000 cells/well) and treated with the carotenoid extracts for 48 h. The carotenoid extracts were dissolved in RPMI medium and served as a stock solution that was later diluted to have a final solvent concentration.

MTT assay

The MTT-assay was used to evaluate the carotenoid extract effect on mentioned cell line's cell viability, and the results were expressed as viable cell percentages with respect to the control. Approximately 2000 cells/well were seeded onto a 96-well plate and allowed to adhere for 24 h. Three replicates of each plate were incubated with different concentrations of carotenoid extracts (0.5, 1, 2, 4, 8 mg/ ml), and viability was recorded at 48 h. After treatment, the medium was removed, and 20 μl of 5 mg/ml solution of MTT (Sigma) in PBS were added to each well. The plate was then incubated for 3 h at 37 °C. Finally, the medium was removed, and 200 μl of the DMSO (Merck) were added in each well to solubilize the blue formazan. Dye absorbance was measured at 560 nm (Abbes et al., 2013[1]).

Carr-price test (Carotenoid test)

The extracted total carotenoids were subjected to TLC using following system: Plate: silica gel 60 F254, Merck; Solvent system: acetone: hexane (40+60); Comparing solutions: regarding to online pigment libraries, stock solution of Neoxanthin, Violaxanthin and Neurosporene were considered to molecular structure alignment (Weber and Davoli, 2003[32]).

A TLC plate, on which the pigment was developed, was sprayed with an absolute chloroform solution of 20 % antimony chloride (III). Mass spectrophotometry test has been carried out in order to align results with online library of similar carotenoids and finally determining the exact structure (Weber and Davoli, 2003[32]).

ResultsStrain identification

According to phenotypic characterization, strain QWT-12 was a Gram-stain-positive, non-motile, coccus, non-spore forming, facultative aerobic bacterium. Figure 1(Fig. 1) shows the colony of strain QWT-12 on nutrient agar with 3 % salt and optical microscope respectively. The phylogenetic position of strain QWT-12 was determined based on 16S rDNA gene sequencing. 1445 bp of 16S rDNA gene of strain QWT12 with accession no. KX073818 was determined. Alignment of this sequence with described species showed this strain belonged to the genus Kocuria with more than 99.8 % similarity to Kocuria marina (Figure 2(Fig. 2)). Biochemical characterization results of QWT-12 strain in comparison with Kocuria marina KMM 3905T have been exhibited in Table 1(Tab. 1).

Effect of various factors on pigment production

Kinetics of bacterial growth and pigment production were investigated in the nutrient broth plus 3 % (w/v) NaCl. Lag phase of the bacterial growth was 15 h and after 23 h, growth reached stationary phase. Pigment production activity was undetectable during the early- and mid-exponential growth phase but started from the end of the exponential phase and continued in the stationary phase (Figure 3(Fig. 3)). To determine the optimal growth conditions yielding the highest pigment production activity, the effect of various culture media was analyzed.

In Figure 4(Fig. 4), comparative effectiveness of each culture medium for cell growth and cell pigmentation were exhibited elaborately. Of the five culture media investigated TSB medium was the best for growth and pigment production. Effects caused by gradient of NaCl, NaNO3, Na2SO4 and KCl in TSB medium on cell pigmentation and OD were shown in Figure 5(Fig. 5). According to these results the proper concentration of different salts for pigment production and growth was 0.1 M for NaNO3, Na2SO4 and KCl and 0. 5 M for NaCl.

MTT assay and IC<sub>50</sub> analysis

In Figure 6(Fig. 6) viability percentage results gained from using five gradient concentration levels of Kocuria carotenoid against seven cancer cell lines have been shown. Abbreviations located beside histogram are due to cell lines while Hu02 has been considered negative control. After calculation for the chi-square test significant IC50s of 1, 4 and 8 mg ml of extracted pigments against MCF-7, (A-549 and MDA-MB-468) and MDA-MB-231 cancer cell lines were obtained respectively. The extracted pigments have no effect on viability of fibroblast cell line and only 20- 30 percent decrease the viability of prostate cancer cell lines.

Pigment analysis

Extracted pigments were separated into several spots by TLC. The orange colored pigment which had the highest affinity for the mobile (solvent) phase migrated towards the top of the TLC, and had Rf equal to the obtained Rf from stock solutions. Two other extracted pigments were also present, including the yellow pigments which have the higher affinity for the stationary (silica) phase. The carr-price test for all spots confirming that these pigments are carotenoids. The UV/light absorption spectra of two yellow pigments were identical to those violaxanthin and neurosporene (Figure 7(Fig. 7)). The absorption maxima of extracted pigments in different solvents including chloroform, ethanol and petroleum ether in comparison with neoxanthin, violaxanthin and neurosporene were exhibited in Table 2(Tab. 2). Number of conjugated double bonds (N) can be estimated following the formulae obtain from (Rivera et al., 2014[24]).

In ethanol:

For both two pigments, it was found that N=9 and according to chemical structure of neoxanthin (N=8), violaxanthin (N=9) and neurosporene(N=9) we could estimate that these extracted pigments are violaxanthin or neurosporene.

Mass spectrophotometry

To more structure elucidation of the extracted pigments, mass spectrophotometry was done for the yellow pigment, as it seems to be the major part of the pigment extraction. Figure 8(Fig. 8), exhibited that the molecular weight (MW) of yellow pigment (yielded from TLC plate) is 538 and this has more similarity to neurosporene (MW=538.8) than violaxanthin and neoxanthin (MW=600). According to all above, it could be estimated that the principle pigment extracted form Kocuria sp. strain QWT-12 is neurosporene.

Discussion

Halophiles which inhabit almost in hypersaline environments like saline ponds, showed great potential toward production of various carotenoids including Dunaliella, producer of beta-carotene, Salinibacter ruber, rich in salinixanthin (de Lourdes Moreno et al., 2012[5]). There exist many factors which influence carotenoid production by microbial cell factory and the most important and highly affecting ones especially in halophiles is salinity of culture condition since, adapting to salinity requires and also leads to altering in metabolic pathways. Hence the possibility of carotenoid over-production could be handled resourcefully (Margesin and Schinner, 2001[13]). Naziri et al. (2014[18]) exhibited optimal total carotenoid production by Halorubrum sp. TBZ126 had occurred in 16.55 % and 20.55 % sodium chloride concentration by using Response Surface Methodology. In this present study, not only we have shown that the maximum carotenoid extraction has correlated to 3 % salinity but also we opted that the most appropriate culture media for cell factory optimization is TSB medium.

Among different carotenoids, neurosporene has commercial importance due to its use as an antioxidant and UV-B radiation protector. It is a tetra-terpenoid carotenoid commonly found in plants and vegetables and also in bacteria, fungi, algae and serves as a precursor for more than 600 carotenoids (Sandmann et al., 1999[26]). This carotenoid is not commercially available at present and hence greatly depends on dietary supplements (Nollet and Toldrá, 2012[20]). We found that the halotolerant Kocuria sp. strain QWT-12 has pigment likewise neurosporene pigments as major carotenoid pigment. Although neurosporene is an intermediate in carotenoid synthesis, its accumulation exhibited in a mutant strain of Rhodobacter capsulatus (Giuliano et al., 1988[8]; Ramaprasad et al., 2013[22]).

Recent preclinical and medicinal studies have shown inverse relation between dietary uptake of carotenoids and risk factors belonged to cancer and tumor occurrence. Not only in vivo studies confirm chemoprevention effects of some carotenoids but also in vitro studies support it by many tissue modeling anticancer activity (Tanaka et al., 2012[29]). Based on current research we exhibited that MTT assay for extracted Kocuria sp. strain QWT-12 carotenoid possess the IC50 against MCF-7, A549, MDA-MB-468 and MDA-MB-231 in 2, 4 and 8 mg/ml concentrations. The cancer preventive potential of carotenoids has been reported in several studies involving cultured cells and animal models (Martini et al., 2010[15]). Carotenoids have been shown to suppress the cancer cell in vitro, by inducing differentiation and apoptosis and cell cycle arrest. Several studies exhibited the viability decrease of several cancer cell lines including colon, melanoma, prostate, oral, lung, and breast cancer cells in presence of different type of carotenoids (Palozza et al., 2003[21]). Abbes et al. (2013[1]) also demonstrated that carotenoid extract of a halophile Archaea, Halobacterium halobium showed significant antiproliferative activity against HepG2 human cancer cell lines.

Conclusion

Although fermentation of carotenoids through microbial cell factory has not reached yet to yield due to plant natural carotenoids but a great spectrum of microbial carotenoids is identified and extracted increasingly and our research established cutting edge ideas toward both preclinical studies and screening for anticancer activity of natural products.

Abbes M Baati H Guermazi S Messina C Santulli A Gharsallah N Biological properties of carotenoids extracted from Halobacterium halobium isolated from a Tunisian solar saltern BMC Complement Altern Med 2013 13 255 Asker D Ohta Y Production of canthaxanthin by extremely halophilic bacteria J Biosci Bioeng 1999 88 617 621 Basu H Vecchio AD Flider F Orthoeter F Nutritional and potential disease prevention properties of carotenoids J Am Oil Chem Soc 2001 78 665 675 Britton G Liaaen-Jensen S Pfander H Carotenoids, Vol. 5: Nutrition and health 2009 New York Springer Science & Business Media de Lourdes Moreno M Sanchez-Porro C Garcia MT Mellado E Carotenoids' production from halophilic bacteria Methods Mol Biol 2012 892 207 217 de Quirós ARB Costa HS Analysis of carotenoids in vegetable and plasma samples: A review J Food Compos Anal 2006 19 97 111 Felsenstein J Confidence limits on phylogenies: an approach using the bootstrap Evolution 1985 39 783 791 Giuliano G Pollock D Stapp H Scolnik PA A genetic-physical map of the Rhodobacter capsulatus carotenoid biosynthesis gene cluster Mol Gen Genet 1988 213 78 83 Gordon HT Bauernfeind JC Carotenoids as food colorants Crit Rev Food Sci Nutr 1982 18 59 97 Irwandi J Noviendri D Hasrini RF Octavianti F Carotenoids: sources, medicinal properties and their application in food and nutraceutical industry J Med Plants Res 2011 5 7119 7131 Konishi I Hosokawa M Sashima T Maoka T Miyashita K Suppressive effects of alloxanthin and diatoxanthin from Halocynthia roretzi on LPS-induced expression of pro-inflammatory genes in RAW264. 7 cells J Oleo Sci 2008 57 181 189 Labi V Grespi F Baumgartner F Villunger A Targeting the Bcl-2-regulated apoptosis pathway by BH3 mimetics: a breakthrough in anticancer therapy? Cell Death Differ 2008 15 977 987 Margesin R Schinner F Potential of halotolerant and halophilic microorganisms for biotechnology Extremophiles 2001 5 73 83 Marmur J A procedure for the isolation of deoxyribonucleic acid from micro-organisms J Mol Biol 1961 3 208 218 Martini S D’Addario C Bonechi C Leone G Tognazzi A Consumi M Increasing photostability and water-solubility of carotenoids: synthesis and characterization of β-carotene–humic acid complexes J Photochem Photobiol B: Biology 2010 101 355 361 Mellado E Moore ERB Nieto JJ Ventosa A Phylogenetic inferences and taxonomic consequences of 16S ribosomal DNA sequence comparison of Chromohalobacter marismortui, Volcaniella eurihalina, and Deleya salina and reclassification of V. eurihalina as Halomonas eurihalina comb. nov Int J Syst Evol Microbiol 1995 45 712 716 Mortensen A Carotenoids and other pigments as natural colorants Pure Appl Chem 2006 78 1477 1491 Naziri D Hamidi M Hassanzadeh S Tarhriz V Zanjani BM Nazemyieh H Analysis of carotenoid production by Halorubrum sp. TBZ126;an extremely halophilic archeon from Urmia Lake Adv Pharm Bull 2014 4 61 67 Nguyen KD Astaxanthin: a comparative case of synthetic vs. natural production. Chemical and Biomolecular Engineering Publications and Other Works 2013 Knoxville, TN Univ. of Tennessee Available from: http://trace.tennessee.edu/utk_chembiopubs/94 Nollet LML Toldrá F Handbook of analysis of active compounds in functional foods 2012 Boca Raton, FL CRC Press Palozza P Serini S Di Nicuolo F Piccioni E Calviello G Prooxidant effects of β-carotene in cultured cells Mol Aspects Med 2003 24 353 362 Ramaprasad E Sasikala C Ramana CV Neurosporene is the major carotenoid accumulated by Rhodobacter viridis JA737 Biotechnol Lett 2013 35 1093 1097 Ravindar J Arulselvi I Elangovan N Isolation and molecular characterization of butanol tolerant bacterial strains for improved biobutanol production J Environ Biol 2014 35 1131 1136 Rivera SM Christou P Canela-Garayoa R Identification of carotenoids using mass spectrometry Mass Spectrom Rev 2014 33 353 372 Saitou N Nei M The neighbor-joining method: a new method for reconstructing phylogenetic trees Mol Biol Evol 1987 4 406 425 Sandmann G Albrecht M Schnurr G Knörzer O Böger P The biotechnological potential and design of novel carotenoids by gene combination in Escherichia coli Trends Biotechnol 1999 17 233 237 Smibert RM Krieg NR Gerhardt P Murray RGE Wood WA Krieg NR Phenotypic characterization Methods for general and molecular bacteriology 1994 Washingon, DC American Society for Microbiology 607 654 Tamura K Peterson D Peterson N Stecher G Nei M Kumar S MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods Mol Biol Evol 2011 28 2731 2739 Tanaka T Shnimizu M Moriwaki H Cancer chemoprevention by carotenoids Molecules 2012 17 3202 3242 Thompson JD Gibson TJ Plewniak F Jeanmougin F Higgins DG The CLUSTAL_X Windows interface: flexible strategies for multiple sequence alignment aided by quality analysis tools Nucl Acids Res 1997 25 4876 4882 Ventosa A Quesada E Rodriguez-Valera F Ruiz-Berraquero F Ramos-Cormenzana A Numerical taxonomy of moderately halophilic gram-negative rods Microbiology 1982 128 1959 1968 Weber RWS Davoli P Teaching techniques for mycology: 20. Astaxanthin, a carotenoid of biotechnological importance from yeast and salmonid fish Mycologist 2003 17 1 30 34 Biochemical test results due to QWT-12 characterization. +; Positive, -; Negative Light absorption maxima of QWT-12 pigments in comparison with Neoxanthin, Violaxanthin and Neurosporene A: QWT-12 colonies under unaided eyes, B: QWT-12 colonies under optical microscope Phylogenetic tree of the QWT-12 strain. Phylogenetic relationships between the QWT12 strain 16S rRNA sequences and other related bacterial sequences. The scale bar corresponds to a 10 % estimated difference in nucleotide sequence positions. Growth curve for QWT-12 in relation with OD and cell pigmentation Effects of NB, MH, TSB, HM and SW culture mediums on cell pigmentation and OD A: KCl gradient effect, B: NaCl gradient effect, C: NaNO<sub>3</sub> gradient effect, D: Na<sub>2</sub>SO<sub>4</sub> gradient effect MTT assay results for five gradient levels of <italic>Kocuria</italic> strain QWT-12 carotenoid against fibroblast cell line (Hu02) and A: Breast cancer cell lines, B: Lung cancer cell line and C: Prostate cancer cell lines UV/Visible spectra of yellow pigments in n-hexane solvent Mass spectrophotometry of yellow pigment extracted from TLC