Natural non-polar fluorescent dye from a non-bioluminescent marine invertebrate, compositions containing the said dye and its uses

Abstract

The present invention discloses a process of extraction, purification and characterization of a non-polar fluorescent dye from a marine echinoderm Holothuria scabra, compositions containing the dye and various applications of the dye, said dye is a natural, cell permeant, nontoxic and environmentally friendly non-polar fluorescent dye.

Description

FIELD OF THE INVENTION

The present invention relates to a bioactive extract containing a natural non-polar and non-proteinaceous fluorescent dye extracted from alcoholic extract of ovarian tissue of a marine invertebrate Holothuria scabra . The invention also provides a process for the extraction, partial purification and characterization of this new non-polar dye. The marine invertebrate mentioned is especially the sea cucumber. Sea cucumbers are echinoderms, members of the group of spiny skinned animals that also includes starfishes and sea urchins. Scientifically called Holothurians, they have elongated tubular bodies which are rubbery and without bony skeletons. They have the following taxonomic position.

BACKGROUND AND PRIOR ART REFERENCES

Sea cucumbers have following taxonomic position.

Subkingdom: Metazoa
Phylum: Echinodermata
Sub-Phylum: Eleutherozoa
Class: Holothuroidea
Subclasses: Aspidochirotacea, Dendrochirotacea, Apodacea
Orders: Dendrochirota, Aspidochirota, Elasipoda, Molpadonia
and Apoda

Amongst these orders sea cucumber Holothuria scabra belongs to:

Order: Aspidochirota
Family: Holothuriidae
Genus: Holothuria
Species:                                                                         scabra

Echinoderms are coelomate invertebrates which are exclusively marine, never colonial, are unsegmented with a basic pentameric radial, symmetry in the adult form, no head or brain, and distinguished from all other animals by structural peculiarities of skeleton and coelom. Class Holothuroidea has animals with body bilaterally symmetrical, usually elongated in the oral-aboral axis having mouth at or near one end and anus at or near the other end. The body surface is coarse, endoskeleton reduced to microscopic spicules or plates embedded in the body wall, mouth surrounded by a set of tentacles attached to water vascular system; podia or tube feet are usually present and locomotory; alimentary canal is long and coiled and cloaca usually with respiratory trees; sexes are usually separate and gonad single or paired tuft of tubules. They are sedentary forms either attached to hard substrate or burrow into soft sediments with anterior and posterior ends projected. There are more than 1000 species of holothuroids. They vary from 2 cm to 2 meter in length. They are among a few of the animals whose habitat is not restricted by ocean depths. Some of the species are reported to be making 50% of life forms at 4000 m and 90% at 8000-m depths. The species Holothuria scabra also called by some as Metriatyla scabra Jaegea is widely distributed in East Africa, Red Sea, Bay of Bengal, East India, Australia, Japan, South Pacific, Philippines, Indian Ocean and other Indo-Pacific regions. It is used for human/animal consumption in Sabah, Malaysia and Indonesia and other Indo-Pacific countries.

Fluorescent dyes are of immense value in the fluorescent probe industries to enable researchers to detect particular components of complex biomolecular assemblies, including live cells with exquisite sensitivity and selectivity (Iain D. Johnson. “Introduction to fluorescence techniques” Chapter 1.pp1 in The Handbook of Fluorescent probes and Research Chemicals by Richard P. Haughland, 6 th edition Printed in the United States of America, 1996). Fluorescent dyes are widely used in labeling of molecular probes for localizing biological structures by fluorescence microscopy e.g in immunoassays, labeling nucleotides and oligonucleotides for in situ hybridization studies, binding to polymeric microspheres and staining of cells for use in imaging studies. Dyes are also used for selective destruction of cells such as in the technique of photodynamic therapy. (Haughland, R. P and Kang, H. C. U.S. Pat. No. 4,774,339 of Sep. 27, 1988; Haughland, R. P and Kang, H. C. U.S. Pat. No. 5,248,782, Sep. 28, 1993).

Non-polar dyes are useful in detection of neutral lipids and other non-polar liquids. The fluorophores with the non-polar quality are most suitable for making conjugants with variety of biomolecules as per the requirement of the reseachers. Two non-polar probes namely NBD probes, NBD dihexadecylamine (D-69) and NBD hexadecylamine (H-429) are primarily been used for fluorescence detection of lipids separated by TLC (The Molecular probes Handbook of Fluorescent probes and Research Chemicals by Richard P. Haughland, 6 th edition Printed in the United States of America, 1996 pp.321-322). The same authors reported three non-polar derivatives of the bodipy fluorophore that offers an unusual combination of non-polar structure and long-wavelength absorption and fluorescence. These dyes are described to have potential applications as stains for neutral lipids and as tracers for oil and other non-polar liquids. For example BODIPY 493/503 (D-3922) is more specific for cellular lipid droplets then staining with Nile red (N-1142). BODIPY 505/515 (D-3921) rapidly permeates cell membranes of live Zebrafish embryos, selectively staining cytoplasmic yolk platelets (Mark Cooper, University of Washington quoted by Molecular probes The Handbook of Fluorescent probes and Research Chemicals by Richard P. Haughland, 6 th edition Printed in the United States of America, 1996 pp.322). Bodipy dyes have a small fluorescence, Stokes shift extinction coeffecients that are typically greater than 80,000 cm −1 M −1 and high fluorescence quantum yields (0.94 for D-3921 in methanol) that are not diminished in water. Their photostability is generally high These Bodipy dyes are used in flash lamp-pumped laser dyes. Bodipy 665/676 (B-3932) can be excited using the 633 nm spectral line of the he-Ne laser or the 647 nm spectral line of the Ar-Kr laser for applications requiring long-wavelength fluorescence detection. (Richard P. Haughland, Molecular probes. The Handbook of Fluorescent probes and Research Chemicals 6 th edition Printed in the United States of America, 1996 pp.321-322). Non-polar fluorescent dyes as dye component in industrial applications are reported in US patents (Fischer, Wolfgang; Deckers, Andreas; Guntherberg, Norbert; Jahns, Ekkehard; Haremza, Sylke; Ostertag, Werner; Schmidt, Helmut. U.S. Pat. No. 5,710,197 released on Jan. 20, 1998 entitled “Crosslinked polymer particles containing a fluorescent dye”; U.S. Pat. No. 5,304,493 dated Apr. 19, 1994 by Nowak, Anthony V Title “Method for detecting a marker dye in aged petroleum distillate fuels; U.S. Pat. No. 4,063,878 dated Dec. 20, 1977 by Weeks, Bruce W entitled “Applying sublimation indicia to pressure sensitive adhesive tape”).

At the website, http://www.uniulm.de/uni/fak/natwis/oc2/ak_wuert/publications.htm there are reported 39 publications of A. K. Wuerthner, most of which pertains to synthesis and design of chromatphores for refractive index materials and photorefractive organic glasses. About nine international patents are also disclosed (S. Beckmann, F. Effenberger, F. Würthner, F. Steybe, DE 44 16 476 (Nov. 16, 1995), WO 95/30679, Preparation of oligothiophenes for use in nonlinear optical materials; K-H. Etzbach, C. Kräh, R. Sens, F. Würthner, DE 19.611.351 (Mar. 22, 1996), WO 97/35926 (Oct. 2, 1997); Farbstoffmischungen, enthaltend Thienyl- und/oder Thiazolazofarbstoffe; Dye mixtures containing thiophene and/or thiazole azo dyes Farbstoffmischungen, enthaltend Thienyl- und/oder Thiazolazofarbstoffe; Dye mixtures containing thiophene and/or thiazole azo dyes; C. Grund, H. Reichelt, A. J. Schmidt, F. Würthner, R. Sens, S. Beckmann, DE 19648564 A1 (May 28, 1998), DE 196 50 958 A1 (Jun. 10, 1998); WO 98/23688 (Jun. 4, 1998) Indoleninmethinfarbstoffe auf Basis von Trifluormethylpyridonen; Trifluormethylpyridone Based Indolenine Methine Dyes; Indoleninmethinfarbstoffie auf Basis von Trifluormethylpyridonen; Trifluormethylpyridone Based Indolenine Methine Dyes; F. Würthner, H.-W. Schmidt, F. Haubner, DE 19643097 A1 (Apr. 23, 1998), Vernetzbare Triarylaminverbindungen und deren Verwendung als Ladungstransportmaterialien; Crosslinkable triarylamines bearing ethynyl groups for use as charge transport materials; F. Würthner, R. Sens, G. Seybold, K.-H. Etzbach, DE 197 11 445 A1 (Sep. 24, 1998), WO 98/41583 (Sep. 24, 1998) Farbstoffsalze und ihre Anwendung beim Färben von polymerem Material; Colorant Salts and their Use in Dying Polymeric Materials)

At website, www.sigma-aldrich.com and in their section immunochemicals of the catalogue “Biochemicals and reagents for life sciences research, 2000-2001 of Sigma-Aldrich has described labeling reagents and cell linker labeling kits pp. 1454-1456. Three US patents by Horan, Paul K, Jensen, Bruce D, Siezak, Sue E, U.S. Pat. No. 4,783,401 of Nov. 8, 1988; Horan, Paul K, Siezak, Sue E in U.S. Pat. No. 4,762,701 of Aug. 9, 1988 and Horan, Paul K, Jensen, Bruce D, Siezak, Sue E in U.S. Pat. No. 4,859,584 dated Aug. 22, 1989 disclosed respectively “viable cell labeling”, in vivo cellular tracking and cell growth rate determination by measurement of changes in cyanine dye levels in plasma membranes.

Nontoxic and cell permeant fluorescent dyes are greatly in demand for their applications in the study of live cell functions, drug delivery, study of various cell organelle and many more. An eukaryotic cell may have several compartments each bounded by a membrane whereas a bacterial cell may consist of a single compartment. The permeability specificity is a characteristic of the cell membranes. A good dye is the one which can show the different parts of the cell at one emission and at different emissions (The Handbook of Fluorescent probes and Research Chemicals by Richard P. Haughland, 6 th edition Printed in the United States of America, 1996).

Dyes with fluorophore attached to various proteins have been synthesized and described in Handbook of fluorescent probes and Research chemicals by Richard P. Haughland 1996. Page 126-128. The range from the blue fluorescent Cascade blue and new AMCA-S dyes to the red fluorescent Texas Red dyes and phycobiliproteins is embodied. The company has high lighted Oregon green conjugates, Rhodol Green conjugates; Bodipy conjugates;Eosin labelled secondary reagents; Red fluorescent Rhodamine Rd-X and Texas Red-X conjugates; Phycobiliprotein conjugates; Cascade blue and AMCA-S conjugates.

All these dyes are synthetic and single one of them emits in one particular spectral range. The combinations of 2-3 dyes are then made for multiple colored experiments. The same company also offers Jasplakinolide, a macro-cyclic peptide isolated from the marine sponge Jaspis jolnstoni as a cell permeant F-actin probe. But it is toxic and exhibits fungicidal, insecticidal, and antiproliferative activity. Most of the currently available dyes in the market are synthetic. Stainfile-Dyes A has given a Dye index of 264 dyes. Out of which 258 are synthetic and only six are natural dyes. (http://members.pgonline.com/˜bryand/dyes/dyes.htm).

Production of synthetic dyes often require use of strong acids, alkalis and heavy metals as catalysts at high temperatures. This makes the processes and the effluents to be discharged an issue of environment degradation. The dyestuff industry is continuously looking for cheaper and more environmentally friendly routes to existing dyes. (Hobson and Wales, 1998. Green Dyes, Journal of the Society of Dyers and colorists (JSDC), 1998,114,42-44).

All of the available dyes are not fluorescent. Bitplane products have displayed list of the 123 fluorochromes in the market and their excitation and emission spectrum (http://www.bitplane.ch/public/support/standard/fluorochrome.htm).

Fluorescence is a phenomenon in which an atom or molecule emits radiation in the course of its transition from a higher to a lower electronic state. It follows Stoke's law, according to which the wavelength of the fluorescent radiation is always longer than that of the excitation radiation. The process of fluorescence is quite different from the phosphorescence and bioluminescence. The term fluorescence is used when the interval between the act of excitation and emission of radiation is very small (10 −8 to 10 −3 second). In phosphorescence, the time interval between absorption and emission may vary from 10 −3 second to several hours (R. Norman Jones, 1966 in: The encyclopaedia of chemistry, 2 nd edition, 1966, Pages 435-436). Bioluminescence is the term used for the light produced as a result of a chemical reaction, occurred at a particular time in a particular cell within the body of a living organism.

A large number of fluorescent dyes are reported in “The Handbook of Fluorescent probes and Research Chemicals” by Richard P. Haughland, 6 th edition Printed in the United States of America, 1996. In the same book on pages 1-6, Ian D. Johnson (1996) described in details the process of fluorescence and its methods of detection in certain molecules called iluorophores or fluorescent dyes by him (generally polyaromatic hydrocarbons or heterocycles). The most versatile currently in use fluorescent dyes are Fluorescein, fluorescein based, BODIPY dyes, and their derivatives. The authors have dealt in with the shortcomings of all these dyes and described their preferences of characteristics of dyes. Many derivatives of the fluorescent dyes and their synthesis are disclosed in US patents (Haughland, R. P and Kang, H. C. U.S. Pat. No. 4,774,339, published on Sep. 27, 1988; Haughland, R. P and Kang, H. C. U.S. Pat. No. 5,248,782 of Sep. 28, 1993; Kang, H. C. and Haughland, R. P, U.S. Pat. No. 5,187,288 published on Feb. 16, 1993; Kang, H. C. and Haughland, R. P in U.S. Pat. No. 5,274,113 of Dec. 28, 1993 and; Kang, H. C. and Haughland, R. P, U.S. Pat. No. 5,433,896 Jul. 18, 1995; Kang, H. C. and Haughland, R. P. U.S. Pat. No. 5,451,663 published on Sep. 19, 1995). Rosenblum Barnett B, Spurgeon S, Lee Linda G, Benson Scott C and Graham Ronald J in international patent No. W00058406, publication date Oct. 5, 2000 reported 4,7-Dichlororhodamine dyes useful as molecular probes.

R. Norman Jones in The encycopaedia of chemistry, 2 nd edition, 1966, Pages 435-436 has described specialty of a good fluorophore. According to him A fluorescent molecule must have a good chromophoric system for absorption of excitation energy and a shielding mechanism to save too rapid dissipation of the excitation energy into vibrational motion before the fluorescence retardation act can occur. He also commented that though the relationship of the molecular structure and the fluorescence of compounds are not well understood there are certain groups, presence of which is associated with fluorescence. For example, in the organic molecule presence of phthalein and aromatic structures such as anthracene and naphthacene are particularly associated with bright fluorescence. Few inorganic compounds fluoresce strongly in the liquid state and in solids, fluorescence is often modified by the presence of trace impurities.

Pigments belong to the categories of inorganic and organic types. The formers are the inorganic chemistry compounds, which are used for various decorative and painting purposes etc. Organic pigments like organic dyes date back to the ancient times. The use of dyes from plants like Eirazil wood, log-wood, Persian berry indigo and madder are reported from near east and far eastern countries even before Biblical times (George L. Clark, 1966 “Encyclopaedia of chemistry, 2nd ed. Pages 833-835).

Debra K. Hobsonand David S. Wales describe “Green dyes” which are produced as secondary metabolites from some groups of living organisms like fungi, blue green algae, sea urchins, star fishes, arthropods and coral reef coelenterates (Journal of the Society of Dyers and Colourists (JSDC), 114, 42-44, 1998). These are anthraquinone compounds, historically of crucial importance in the dyestuffs industry.

Variety of carotenoid pigments are reported from the carotenoid-producing bacterial species (U.S. Pat. No. 5,935,808 published on Aug. 10, 1999, inventors Hirschberg, et al and U.S. Pat. No. 5,858,761, Jan. 12, 1999 inventors Tsubokura, et al). Collin; Peter Donald in his U.S. Pat. No. 6,055,936 published on May 2, 2000 disclosed sea cucumber carotenoid lipid fractions and process. Bandaranayake, W. M. and Des Rocher, A 1999 (Marine biology 133;163-169) described carotenoid pigments from the body wall, ovaries and viscera of Holothuiria atra from Australia.

All these colorants and dyes are however not fluorescent. Fluorescent dyes most of which are synthetics are disclosed in several international patents and US patents. These have been used in variety of applications. The amount of patents in this field shows the importance of these dyes. Synthetic parazoanthoxanthin A (m.w.214.2), emitting fluorescence at lambda (em) 420 nm, was found to be a pure competitive inhibitor of cholinesterases. Sepcic K, Turk T, Macek P (Toxicon, 36 (6): 937-940,1998). Welch; David Emanuel (U.S. Pat. No. 5,989,135 released on date Nov. 23, 1999 disclosed a luminescent golf ball.

White et al. (U.S. Pat. No. 6,110,566, dated Aug. 29, 2000 and WO9920688) described a flexible polyvinyl chloride film that exhibits durable fluorescent colors.

Dipietro Thomas C (International patent WO9938916) disclosed the use of fluorescent polymeric pigments in variety of paints, inks and textiles. Cramer Randall J (Patent No. EP0206718 published on Dec. 30, 1986) described a composition with fluorescent dye for bleaching and brightening of polymer.

Leak detection is another utility disclosed by some (Leighley; Kenneth C. U.S. Pat. No. 6,056,162 dated May 2, 2000). Cooper et al. U.S. Pat. No. 6,165,384 published on Dec. 26, 2000 disclose a full spectrum fluorescent dye composition for the same purposes. Lichtwardt et al. U.S. Pat. No. 5,902,749 dated May 11, 1999 use fluorescent dye in an automated chemical metering system.

There are reports on few fluorescent natural dyes available. A green fluorescent protein GFP has been described from the pacific jellyfish, Aequora aequora by Shimomura, O, Johnson, F. H. and Saiga, Y; in Journal of cellular and comparative physiology, 59, 223-239, 1962, Chalfie M in 1: Photochem Photobiol October 1995 62 (4): 651-6 “Green fluorescent protein”; Youvan D C, Michel-Beyerie ME “Structure and fluorescence mechanism of GFP in National Biotechnology Oct. 14, 1996 (10): 1219-20 and Chalfie M, Yuan Tu, Ghia Euskirchen, William W. Ward, Douglas C Prasher in SCIENCE 263 (1994) 802-805 reported that GFP purified is a protein of 238 amino acids. It absorbs blue light maximally at 395 nm with a minor peak at 470 nm and emits green light at the peak emission of 509 nm with a shoulder at 540 nm. This fluorescence is very stable and virtually no photo bleaching is observed.

GFP with fluorescence in other wavelengths in the ranges of red and yellow are described from non bioluminescent anthozoans, particularly Discosoma coral. Gurskaya N G, Fradkov A F, Terskikh A, Matz M V, Labas Y A, Martynov V I, Yanushevich Y G, Lukyanov K A, Lukyanov S A in 1: FEBS Lett Oct. 19, 2001; 507 (1): 16-20n described GFP-like chromoproteins as a source of far-red fluorescent proteins. Wachter R M, Elsliger M A, Kallio K, Hanson G T, Remington S J. In 1: Structure Oct. 15, 1998; 6(10): 1267-77 described “Structural basis of spectral shifts in the yellow-emission variants of green fluorescent protein”. Fradkov A F, Chen Y, Ding L, Barsova E V, Matz M V,Lukyanov S A “Novel fluorescent protein from Discosoma coral and its mutants possesses a unique far-red fluorescence. In 1:FEBS Lett 2000 Aug. 18: 479 (3): 127-30. They describe a novel gene for advanced red-shifted protein with an emission maximum at 593 nm was cloned from Discosoma coral. The protein, named dsFP593, is highly homologous to the recently described GFP-like protein drFP583 with an emission maximum at 583 nm. They developed various mutants of both these genes. A hybrid mutant variant resulted I a mutant variant with a uniquely re-shifted emission maximum at 616 nm. Matz M V, Fradkov A F, Labas Y A, Savitsky A P, Zaraisky A G, Markelov M L, Lukyanov S A. 1: Nat Biotechnolo 1999 Dec: 17(10): 969-73.

In the south east and south pacific countries sea cucumbers are well known for their use in the health food and drug industry as a food item or ingredient to various drug compositions especially for inflammation of joints, sprains and other therapeutics. Several US and International patents are on record and screened. (Fan Hui-Zeng, Yu Song, Yamanaka E, Numata K, Oka T, Suzuki N, muranaka Y in U.S. Pat. No. 5,519,010 dated May 21, 1996; Weiman, Bernard, U.S. Pat. No. 5,888,514 published on Mar. 30, 1999; Katsukura, Kitazato, Kenji Yamazaki, Yasundo U.S. Pat. No. 5,993,797 dated Nov. 30, 1999; Henderson, R. W; Henderson, T and Hammd, T U.S. Pat. No. 6,255,295 dated Jul. 3, 2001; Shinya U.S. Pat. No. 6,203,827 of Mar. 20, 2001; U.S. Pat. No. 5,770,205 patent by Collin Peter Donald published on Jun. 23, 1998 and WO patent no. 0001399 published on Jan. 13, 2000; Kovalev V G, Sementsov V K, Slutskaja, Akulin V N, Timchishina G N in RU 2147239 published on Apr. 10, 2000; Li Zhaoming, Zhu Beiwei CN 1286926 dated Mar. 14, 2001 Qu Jianhong, Song Xiuqin, Zheng Fuqiang CN 1223131 dated Jul. 21, 1999; Wufa Zhuang Wufa, Meizheng Zhuang CN 1142365 dated Feb. 12, 1997; Fang Hua CN1312031 dated Sep. 12, 2001 and Ding Cunyi CN1173290 dated Feb. 10, 1998, Collin Peter Donald W09937314 published on Jul. 29, 1999). The use of the ingredients originated from sea-cucumber in Anti HIV drug are disclosed (Hoshino Hiroo EP 410002 dated Jan. 30, 1991 and Hoshino Hiroo EP495116 dated Jul. 22, 1992). In view of their importance the animals are tried to be cultivated under captivity (Annie Mercier, S C Battaglene and Jean-Francois Hamel in Journal of experimental Marine Biology and Ecology Volume 249 issue 1: 89-110. 2000 “Settlement preferences and early migration of the tropical sea cucumber Holothuria scabra ). Gu Zaishi, Wang Shuhai, Zhou Wei disclosed “Ecological reproducing method for Stichopus japonicus “in patent No. CN1179261 dated Apr. 22, 1998.

But as all these patents are not directly of relevance to the topic of the present patent so they have been not included as reference.

Goswami, Usha and Ganguly, Anutosh has filed a patent on a natural fluorescent dye from a marine invertebrate (CSIR, NF-140/2001; U.S. patent application Ser. No.: 09/820654 filed on Mar. 30, 2001). This pertains to the crude extract from Holothuria scabra , which has the fluorescent qualities at three different wavelengths when excited at different UV and visible ranges of the spectra of light. The invention also provides a process of the extraction, purification and characterization of this new dye, which is a partially purified natural dye from a sea cucumber. The utilities of the dye as a epifluorescent stain and non-radioactive fluorescent dye useful for labeling of molecular probes for in situ hybridization studies is described besides several other qualities of the dye as a drug. In this patent prior art, we have dealt in details about the pigments, synthetic dyes and natural dyes from terrestrial plants and microbes. (U.S. Pat. No. 4,452,822 published on Jun. 5, 1984, inventors Shrikhande, Anil J., U.S. Pat. No. 5,321,268 of Jun. 14, 1994 by Crosby David A and Ekstrom Philip A; U.S. Pat. No. 5,405,416 published on Apr. 11, 1995 authors Swinton; Robert J, U.S. Pat. No. 5,858,761 published on Jan. 12, 1999, inventors Tsubokura, et al. U.S. Pat. No. 5,902,749 of May 11, 1999 inventors Lichtwardt et al. U.S. Pat. No. 5,908,650 published on Jun. 1, 1999 inventors Lenoble, et al. U.S. Pat. No. 5,920,429 published on Jul. 6, 1999 Burns et al. U.S. Pat. No. 5,935,808 on Aug. 10, 1999 of Hirschberg, et al; U.S. Pat. No.5,989,135 of Nov. 23, 1999 inventors Welch; David Emanuel; U.S. Pat. No. 6,055,936 of May 2, 2000; Collin; Peter Donald; U.S. Pat. No. 6,056,162 May 2, 2000; Leighley; Kenneth C.; U.S. Pat. Nos. 6,103,006 Aug. 5, 2000 DiPietro; Thomas C.; 6,110,566 Aug. 29, 2000 White et al. 6,140,041 Oct. 31, 2000 LaClair; James J. 6,165,384 Dec. 26, 2000 Cooper et al.; U.S. Pat. No. 6,180,154 Jan. 30, 2001 Wrolstad et al. EP0206718 published on Dec. 30, 1986 inventors Cramer Randall J; IE901379 of Jan. 30 1991 Lee Linda G; Mize Patrick D; WO9010044 of Jul. 7, 1990. Swinton; Robert J; AU704112 published on Oct. 7, 1997 inventors Burns David M; Pavelka Lee A; DE19755642 of Jun. 24, 1999 of Weimer Thomas D R.; WO9938919, Sep. 28, 1999 Laclair James J; WO0058406 of Oct. 5, 2000 by Rosenblum Barnett B et al.; WO9938916 of Aug. 15, 2000 inventors DiPietro; Thomas C; WO9920688 of Aug. 29, 2000 inventors Pavelka Lee et al.; WO9920688 of Aug. 29, 2000 inventors

White et al. The multiple uses oiF fluorescent dyes in the molecular biology research, in industrial applications and in life saving devices etc. are also described. Collin, P. D in his U.S patents of Jun. 23, 1998, Mar. 2, 1999 and Nov. 16, 1999 respective U.S. Pat. Nos. as 5,770,205, 5,876,762 and 5,985,330 have described therapeutic properties of various body parts of sea cucumber.

In another patent application, inventors of the present application i.e. Goswami, Usha and Anutosh Ganguly (U.S. Provisional application No. 60/317,190 filed on Sep. 6, 2001) has described a novel organosilicon Si—O—R type of compound and multiple fluorescent natural dye purified from the body wall extract of a marine invertebrate Holothuria scabira. The compound is a polysacchride fluorochrome having a phenolic fluorophore part and is connected to a silicon matrix around it through the sulphate bonds. This silcon part is an integral part of the core molecule and takes part in the metabolism of the animal. The compound is rich in sulfur. The invention also provides a process for the extraction, purification and characterization of the novel compound and the multiple fluorescent dye from a living marine organism, especially sea cucumber. Further, the compound can be an easily miscible ingredient in compositions of Dye industry, Cosmetic industry and pharmaceutical industries.

In this patent a large body of literature upon fluorescent dyes reported in the Handbook of Fluorescent probes and Research Chemicals by Richard P. Haughland, 6 th edition Printed in the United States of America, 1996 are incorporated. In US and international patents many derivatives of the fluorescent dyes and their synthesis are disclosed (Haughland, R. P and Kang, H. C. U.S. Pat. No. 4,774,339, published on Sep. 27, 1988; Haughland, R. P and Kang, H. C. U.S. Pat. No. 5,248,782 of Sep. 28, 1993; Kang, H. C. and Haughland, R. P, U.S. Pat. No. 5,187,288 published on Feb. 16, 1993; Kang, H. C. and Haughland, R. P in U.S. Pat. No. 5,274,113 of Dec. 28, 1993 and; Kang, H. C. and Haughland, R. P, U.S. Pat. No. 5,433,896 Jul. 18, 1995; Kang, H. C. and Haughland, R. P. U.S. Pat. No. 5,451,663 published on Sep. 19, 1995, Rosenblum Barnett B, Spurgeon S, Lee Linda G, Benson Scott C and Graham Ronald J, international patent No. W00058406, publication date Oct. 5th, 2000 reported 4,7-Dichlororhodarnine dyes useful as molecular probes).

All these references pertain to the present patent also.

The applicants have adopted a different approach from their earlier patents and those reported by other workers.

The dyes reported in our earlier patents were though natural but they were toxic. The spectral ranges of emissions at various excitation wavelengths were also different. The dyes were toxic, and not suitable for in situ studies of live cells. Their applications and uses in the biomedical and engineering sciences were different.

The dye now reported is though also a natural dye but is a non-polar multiple fluorescent flurophore extracted from the female gonads of a non-bioluminescent invertebrate. The marine animal source is a holothurian, sea cucumber called Holothuria scabra which is a new source for a non-polar fluorescent dye. The dye is environmentally friendly, as unlike the synthetic dyes there is no need of intervening steps of strong acids and alkalis in their productions. Unlike the earlier described carotenoid pigments from the sea cucumber ovaries this dye is not a carotenoid pigment. It is a non-polar fluorophore easily separable from the conjugant biomolecule, which is a negatively charged protein.

Unlike most synthetic fluorescent dyes, our dye does not need to be mixed with another dye for getting different fluorescence hues at different wavelengths. They themselves emit six different colored fluorescence at three different excitation wavelengths, which can have multiple uses. The cell constituents show a contrasting staining from the background where only dye solution is present.

The present dye is cell permanent and permeates through plasma membrane, cytosol, nuclear membrane, nucleoplasm and chromosomes.

Once the dye attaches to the cell membranes it is stable at the room temperature for months and does not get photobleached and contaminated by microbes. Its fluorescence does not get deteriorated at high and low temperatures unlike extracts of some algae and luminescent organisms.

The dye is nontoxic to the E.coli bacteria and the sex cells and larvae of estuarine and marine animals. So its effluents will not kill the marine and estuarine animals larval stages. It is a nontoxic and eco-friendly dye.

Another important feature of the dye is that it shows fluorescence in only the live and fixed tissues. The dead ones are not stained and do not give any fluorescence. One important aspect of the dye is its making compositions and kits for non-radioactive in situ labeling of molecular probes and counter staining. At different wavelength excitations it gives the effect equivalent to color of DAPI, FITC and PI and other marketed fluorescent probes. The dye is a natural multiple fluorescent dye. Actually, this single dye covers the colors of wavelength spectrum of 123 flurochromes presently known in the market (see Bitplane products (Fluorochrome) on the Internet (http://www.bitplane.ch/public/support/standard/Fluorochrome.htm).

Yet another aspect is its use as a nontoxic fluorochrome stain in epiflourescence microscopy for the live cells. The dye is a natural dye and not synthetic which is permeant through various membranes and stains them differentially. This application provides a simple and quick method of checking cytogenetical preparations for multiple uses like molecular diagnostics using fluorescent in situ hybridization techniques, rapid diagnosis of bio-contamination in tissue cultures, food industry and industrial preparations, flow-cytometry etc.

Yet another aspect of the dye is its use as a component of the non-radioactive labeling kits for advanced molecular biology applications where protein dyes are needed for studies of live cell functions.

OBJECTS OF THE INVENTION

The present invention discloses a process of extraction, purification and characterization of a fluorescent dye solution from 70% alcoholic solution of ovarian tissue of a marine echinoderm. This is al natural dye, which has non-polar coloring part. Bioactive extract containing a natural non-polar and non-proteinaceous fluorescent dye extracted from alcoholic extract of the ovarian cells and a process of extraction, purification and characterization of a fluorescent pigment from ovarian extract of a marine echinoderm. The pigment is a natural dye, which is a non-polar fluorophore. The dye emits fluorescence in multiple fluorescent excitation ranges of UV and visible light spectra. It further discloses the chemical, physical, epifluorescent microscopic nature of the dye. The nontoxic, cell membrane permeable qualities are seen.

The main object of the present invention is to provide a natural nontoxic ecofriendly non-polar multiple colored fluorescent dye from the ovarian tissue of sea-cucumber Holothuria scabra.

Another object of the invention is to provide a process for extraction, partial purification and characterization of the said dye from the marine animal Holothuria scabra which is a non bioluminescent marine invertebrate.

Another object of the invention is to provide a dye which is cell membranes permeable, giving demarcation of cell partitioning and having a visual effect at single and multiple emission ranges of UV and visible light spectral wavelengths.

Another object of the invention is to develop a dye with high quantum of fluorescence

Another object of the invention is to develop a dye with less photobleaching.

Another object of the invention is to develop a longer time photo stable dye at the room temperature.

Another object of the invention is to use the dye for checking survival and growth of animal and bacterial cells.

Yet another object of the invention is to provide compositions employing the dye obtained from the tissues of Holothuria scabra.

Still another object of the invention is to provide a dye that emits fluorescence in six different wavelength ranges of UV and visible light spectra on particular excitation with three wavelengths.

Another object of invention is to observe the fluorescence and visible spectroscopic analysis and range of emission wavelengths.

Yet another object is to observe the six different fluorescence colored emissions of the dye in UV and visible ranges of epifluorescence microscopy cubes.

Still another object of the invention is to observe the effect of fluorescence staining of the cytogenetical slides to screen chromosomes, cells and tissues by using the dye of the invention.

Yet another object of invention is to see its nontoxic nature by performing experiments with bacteria.

Yet another object of invention is to see its nontoxic nature by performing experiments with marine animal cells.

Yet another object of the invention is its application for checking bacterial contaminations in food industry.

Yet another object of the invention is to observe the fluorescence and visible spectroscopic analysis and range of emission wavelengths.

Yet another object of the invention is that the dye is useful as a non-radioactive label of fluorescent molecular probes.

Still another object of the invention is that the dye does not get quenched fast in the excited light and photobleaching does not occur while screening slides.

Yet another object of the invention is to observe the fluorescence and visible spectroscopic analysis and range of emission wavelengths.

Yet, another object of the invention is that the dye is useful as a non-radioactive label of fluorescent molecular probes.

Another object of the invention is that the dye is highly stable at the room temperature of its own as well as when attached to the cell membranes.

Still another object of the invention is that its fluorescence quality does not get deteriorated even at extremely high and low temperatures.

Yet, another object of the invention is to develop kits for non-radioactive labeling of molecular probes and counter staining.

Yet, another object of the invention is industrial use of the fluorophore for synthesizing biomolecule-conjugants for flow-cytometry, micro-arrays, immunoassays and several other molecular applications as per the requirements of the researcher.

Still another object is to develop kits containing the fluorescent dye as in situ hybridization non-radioactive labelling kits for molecular probes.

Still another object is to develop low cost LIVE/DEAD Viability/Cytotoxicity kit for animal cells.

Still another object is to develop low cost LIVE/DEAD Viability/Cytotoxicity kit for bacteria.

Still another object is to develop low cost LIVE/DEAD Viability kit for sperms.

Still another object is to develop low cost LIVE/DEAD Viability kit for yeast cells.

Still another object is to develop low cost LIVE/DEAD Viability kit for animal cells.

Still another object is to develop low cost bacterial gram stain and LIVE/DEAD Viability kits.

Still another object is to develop low cost LIVE bacterial gram stain kit.

Still another object is to develop low cost bacteria counting kit.

Still another object is to develop low cost kits for animal cells with simple steps.

Still another object is to develop kits containing the fluorescent dye for cell culture contamination detection.

Still another aspect of the invention is the specificity and reliability. The live cells color and give fluorescence and the dead cells do not show any fluorescence.

Still another aspect of the invention is to use a single dye in the kits in place of presently used 2 dyes for live/dead cells detection.

Still another aspect of the invention is to develop less expensive and non-hazardous proliferation assays than the radioisotopic techniques.

SUMMARY OF THE INVENTION

Accordingly, the invention provides a bioactive extract containing a natural non-polar and non-proteinaceous fluorescent dye extracted from alcoholic extract obtained from ovarian cells of a non bioluminescent marine organism called sea-cucumber Holothuria scabra . The invention also provides a process for extraction, isolation and characterization of the said dye, which is a fluorophore detached from a protein conjugant. The said dye is partially purified and is in a solution form. The dye is tested for its nontoxic nature upon animal and bacterial live cells. The dye compositions will be useful as fluorescent epifluorescence microscopic stain, as fluorescent dye ingredient in multiple type of applications in the biomedical, molecular biology, microbiology, cell biology, recombinant technologies etc. and in formulation of new biomolecule conjugarits for applications in fluorescent probes.

DETAILED DESCRIPTION OF THE INVENTION

After much research, the applicants have now identified a novel natural nontoxic fluorescent dye obtained from tissue of marine animals, especially from invertebrates and more specifically from the sea-cucumber Holothuria scabra .

Subkingdom: Metazoa
Phylum: Echinodermata
Sub-Phylum: Eleutherozoa
Class: Holothuroidea
Subclass: Aspidochirotacea
Order: Aspidochirota
Family: Holothuridae
Genus: Holothuria
Species:                                                                         scabra

The invention further provides a natural non-polar multiple fluorescent dyes which is obtained from the ovary of the animal and which is nontoxic to live cells. It also describes the physical and chemical nature of the dye and its stability in direct light, high and low temperatures. The said dye has six colored fluorescent emissions at three different excitation wavelengths of UV and visible light spectrum. The invention also relates to screening of cells under fluorescence microscope for a rapid check of contaminations and cell survival. The invention is also concerned with the uses of the dye as a non-radioactive label of protein, DNA and RNA molecular probes for advanced molecular diagnostics, epi-fluorescence microscopy for single double and multiple staining of chromosomes, cells and tissues, fluorescence in situ hybridization applications, and biocontamination check, in aquaculture and biomedical sciences for enhancement of fertility, as a component of kits where studies on live cells are required, novel remote sensing devices, underwater probes, life saving devices, mark the location of crashed aircraft, life rafts and Defence equipment for example rockets, various fluorescence applications in sub zero temperature conditions and many more. The dye is environmentally ecofriendly as it does not kill larvae of the estuarine and marine animals.

The invention describes fluorescent dye obtained from marine animals, which either absorb sunlight for their physiological functions or are exposed to longer duration of sunlight and appear to have evolved mechanisms of fluorescence at different wavelengths. Like the phytoplankton, picoplankton and photosynthetic bacteria absorb sunlight for their photosynthetic functions, the required wavelengths of light spectra are used in the chemical pathways and extra light is emitted following Stoke's law.

The invertebrate animals who do not have an extra outer armor like a shell and conspicuous defence organs, who have hard and spiny skin, who have a strong endoskeleton formed of ossicles, are sedentary or slow mobility, have long hours of exposures to direct sunlight, live in sand or crevices may show fluorescence.

The present invention seeks to overcome the drawbacks inherent in the prior art by providing highly efficient and selective methods for extraction, purification and characterization of a dye from a marine invertebrate and its multiple uses in making kits for molecular diagnostics using non-radioactive labels, molecular markers, epiflourescence microscopy, component of new instrumentation devices for land and underwater probes, cosmetic industry, food industries and defense purposes etc.,

The said marine invertebrate is an echinoderm taxonomically called Holothuria scabra belonging to the class Holothuroidea. The product of the invention is a novel nontoxic multicolor fluorescent protein dye, which is reported for the first time. The animals were collected from the shores of central West Coast of India during low tide, brought to the laboratory and maintained in glass tanks containing seawater of salinity 30-32% per par. The animals were adults and sexually mature. The taxonomic position was identified as above.

In fact, most of the dyes available are synthetic in nature. There are only 6 types of natural dyes. This includes dyes obtained from all living organisms. The fluorescent dye reported in the present invention is the only one of its specialty of multicolor fluorescence nontoxic, living cell membrane permeant extracted from ovarian tissue of a marine sea cucumber and has abilities to be conjugated to biomolecules.

As used herein the term dye is used for a dye solution, which does not get decolorized by a reducing agent. The said dye imparts color to the fibre, cellulose, cell membranes etc. It is called a natural dye as the source is from a marine animal found commonly in the nature along shores, shallow and deep waters of the world and is not a synthetic pigment. A fluorescent dye is one, which on excitation at a particular wavelength during the transition from a higher to the lower electronic state within a very short duration it emits light.

Multiple colored fluorescence means the emission of different colored light when excited at different ranges of wavelengths. It emits blue, yellowish green and orangish red colored hues of fluorescence at excitations with different spectra of UV and visible light.

Cell membrane permeant means that the dye passes through the pores of the live cell and nuclear membranes of the cell and imparts it multicolored fluorescence in the shades of blue, bluish white, green, yellow orange and orangish red depending upon excitation with the UV, blue and green wavelength ranges.

The dye does not stain the already dead cells of both animal and bacteria.

The nontoxic to live cells means when tested upon live cells of both marine animal and bacteria ( E.coli ), their cells do not die.

Photostability at room temperature means when left on the bench at room temperature (˜28 degree centigrade) the florescence quality does not deteriorate. Photostabilty of dye after attaching to cell membranes means the continuation of fluorescence emission after staining the live and fixed cells with the said dye.

The molecular diagnostics as used herein means the use of the dye as a non-radioactive label of molecular probes for fluorescent in situ hybridization applications in molecular cytogenetics and as markers in microarrays, and molecular biological studies.

The epifluorescent microscopy here pertains to the microscopic studies of cyto-genetical preparations of slides by using the present dye as a stain and recording different colored fluorescence when observed under different cube configurations emits a particular colored emission on excitation with known fluorochromes. The fluoro-chrome cubes WUB, WB, WG are the designated filter cube configurations of the Olympus BX-FLA reflected light fluorescence attachment for different wavelengths.

Accordingly, the present invention provides a bioactive extract containing non-polar and non-proteinaceous fluorescent dye obtained from alcoholic extract ovarian cells of a non bioluminescent marine organism Holothuria scabra occurring in intertidal, submerged, shallow and deep waters, usually abundant in shaded areas such as acloves, crevices, ledges, overhangings, rocky and sandy habitats; dull to bright coloured with or without exo- and endo skeleton, sessile, sedentary drifters, ektonic with varied swimming power usually nocturnal in habit, liabile to active predation, with and without luminescent and fluorescent pigments giving emissions in few to all wavelength ranges of UVB,UVA visible colored spectrums and infra red spectrum.

One embodiment of the invention relates, to the bioactive extract obtained from the marine organism, which is useful as a natural fluorescent dye having the following characteristics:

i. no decolorization by a reducing agent,

ii. it is a natural compound,

iii. crude extract of the dye is orange in color,

iv. semi purified dye solution is bright orange in color for the naked eye,

v. under tube light it emits variety of colors of the visible light spectrum,

vi. the pigment separated form protein part is insoluble in water and alcohol,

vii. the partially purified dye pigment is soluble in ether.

viii. the dye is a non-polar dye having pH 7.0,

ix. absence of reduciable chromophore,

x. dye solution emits six different colored fluorescence at 3 different wavelengths of the UV and visible ranges of the fluorescent cubes of an epifluorescence microscope, depending upon whether it is the dye solution alone or the cells on which dye has permeated and attached,

xi. fluorescence of blue color emission occur in the 450 nm-470 nm range on excitation under ultra violet cube WU-330 nm-385 nm excitation range,

xii. fluorescence of yellowish green color emission occurs in the 510 nm-570 nm range on excitation under WB cube of 450 nm-480 nm excitation range,

xiii. fluorescence of orange color emission occurs in the 610 nm-650 nm range on excitation under WG cube of 510 nm-550 nm excitation range,

xiv. the dye emits hues of yellowish grays under the ordinary transmitted light bulb of the epifluorescence microscope when seen under 100×oil immersion objective,

xv. the dye emits fluorescence colors even at a dilution range of 1:40000 times

xvi. the fluorescence of the extract persisted even up to 1 year when preserved at about 4° C.,

xvii. the fluorescence of the dye is highly photostable and does not get deteriorated by long exposures to direct light,

xviii. the fluorescence of the dye does not change even when frozen at −20° C., a temperature at which the molecules are unable to attain the energy necessary for activation like in extracts from luminescent organisms,

xix. the dye is nontoxic to the living cells of eukaryotes and prokaryotes ( E. coli )

xx. the dye is permeable to cell membranes,

xxi. the dye is impermeable to dead eukaryotic cells and dead prokaryotic cells, and

xxii. the dye is non degradable even after staining the cell components.

Another embodiment of the invention, the multicolored emissions of the dye at different wavelengths of excitations are comparable to the fluorochrome microscopic stains available in the market.

Still another embodiment, the blue colored fluorescence of the present dye is comparable to the emission of same color by DAPI fluorochrome at the same wavelength excitation, used as components of the non-radioactive labeling kits of biochemistry, cell biology, immuno-chemistry and molecular biology.

Still another embodiment, the yellow colored fluorescence of the dye under the visible range is comparable to the same colored emissions of Auramin used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

Yet another embodiment, the yellow colored fluorescence of the said dye in the visible range is comparable to the same colored emissions of FITC used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry and molecular biology.

Yet another embodiment of the invention provides a dye having orange colored fluorescent emission, comparable to the orange fluorescence color of Propidium Iodide fluorochrome which is used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

Yet another embodiment of the invention provides a dye having orange colored fluorescent emission, comparable to the orange fluorescence color of Rhodamine fluorochrome used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

Yet another embodiment of the invention provides a dye having orange colored fluorescent emission, comparable to the orange fluorescence color of TRITC fluorochrome used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

Yet another embodiment of the invention provides a stable dye at room temperature and has a long shelf life.

Yet another embodiment of the invention the molecular and radioactive kits of the said dye can be exported at the room temperatures.

Yet another embodiment of the invention provides a dye having characteristics of at least one hundred different fluorochromes available in the market namely DAPI, Hoechest 33258, Hoechest 33342, FITC, acridine orange, auramine, Rhodamine, TRITC, and propidium iodide, etc.

Yet another embodiment of the invention provides a dye used in all applications in place of Phycobiliproteins.

Yet another embodiment of the invention, the said dye under bright field of fluorescent microscope when seen under 10×objective, the hues of bluish grays produce a phase contrast effect which is useful in rapid screening of cytogentical, cytological, and histochemical slides and save expenses on the extra phase contrast accessory component of microscope.

Yet another embodiment of the invention, the said dye under 100×oil immersion objective of an ordinary transmitted light microscope the proteins of yolk, nucleoplasm and chromatin of actively dividing cleavage cells show different colors of staining in the hues of brownish yellow for former, yellow for the latter and dark blue for the last cell component, which is useful in rapid bioassays of effect can be seen on the various histochemical components of the cells.

Yet another embodiment of the invention, the fluorescence color emissions follow Stoke's law of fluorescence.

Yet another embodiment of the invention, the microphotographs with Kodak film rolls show hues of the adjacent color emission wavelengths such as blue color fluorescence under the epifluorescence.

Yet another embodiment of the invention, the microphotographs with Kodak film rolls shows hues of the adjacent color emission wavelengths like when seen yellow color fluorescence under the epifluorescence microscope in microphotograph the hues of green also found.

Yet another embodiment of the invention, orange fluorescence color is seen under the epifluorescence microscope in microphotograph, the hues of red also found.

Yet another embodiment, the cytogenetic slides seen under all fluorescences gives a counterstain effect of cells and cell components versus the background color where no specimen but only dye is present.

Yet another embodiment, the diluted dye with water in the ratio above 1:4,50,000 to 1:9,00,000 times give fluorescence of six colors at three different wavelengths.

One more embodiment of the invention provides compositions comprising bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with suitable additives for the following useful applications:

i. preparing fluorescent color coating compositions and inks useful in variety of paints, inks, textile;

ii. as a fluorescent molecular probe in situ hybridization kits for molecular diagnostics;

iii. used in experiments where various applications of fluorescent dyes are needed to be performed at field stations situated at subzero degree temperature areas;

iv. useful as fluorochrome stains for epifluorescence microscopy;

v. useful in cell permeant dye compositions;

vi. a composition of fluorescent dye for bleaching and brightening polymer;

vii. leak detection with a full spectrum fluorescent dye;

viii. use in automated chemical metering system;

ix. to mark location of crashed air-crafts, life crafts, and equipment for example rockets;

x. under sea probes;

xi. chromatophore sunscreen component of cosmetics creams and lotions;

xii. fluorescent in situ hybridization application kit component for molecular diagnostics;

xiii. component of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology for labeling of DNA, RNA, Proteins and enzymes;

xiv. immunofluorescent detections;

xv. counterstain of DIG-labeled oligonucleotide probes and Anti-DIG Fab-fragments;

xvi. single and multiple flow cytometry applications;

xvii. fluorochrome stains for epifluorescence microscopy;

xviii. for a quick check of biocontamination in the health food industry, cosmetic industry, pharmaceutical and chemical industries;

xix. for rapid estimations of biocontaminants in laboratory cultures;

xx. for a rapid check of biopollutants under field conditions;

xxi. for a rapid check of dead and live bacteria E.coli;

xxii. a natural colorant;

xxiii. a bioactive composition of the fluorescent dye in the ratio of 1:400000 in ether is sufficient to produce fluorescences of six colors at three different wavelengths and a phase contrast effect under transmitted light;

xxiv. a dye for various fluorescent applications to be performed in areas of sub zero temperatures;

xxv. a dye for making conjugants with variety of biomolecules;

xxvi. for cell permeant membrane dye compositions;

xxvii. for identification of dead and live cells in tissue cultures;

xxviii. for dye compositions in biosensors;

xxix. as dye composition in molecular and microbiological kits; and

xxx. a non-polar dye for detection of lipids and oils.

One more embodiment of the invention relates to a process for preparation of a bioactive extract containing a natural fluorescent dye from Holothuria scabra sea cucumber, said process comprises the steps of:

a) collecting the marine organism from seashore,

b) maintaining the organism in tanks containing seawater without any mechanical aeration overnight,

c) dissecting the washed animals and removing the female gonads,

d) extracting with 70% ethyl alcohol to obtain yellowish orange solution,

e) repeating the extraction steps 3-4 times to obtain colored solution,

f) filtering the above solution through Whatman No. 1 filter paper to obtain partially purified extract,

g) dissolving the extract obtained in step (f) in solvent ether, and

h) filtering through Whatmaini No 1 filter paper to obtain clear yellow colored solution named as “Non-polar fluorescent dye solution

Another embodiment of the invention, the said dye solution is diluted further with water/seawater, in the ratio ranging between 1:400,000 to 1:900,000 times give fluorescence of six colors at three different excitation wavelengths.

Still another embodiment of the invention, wherein bioassays are conducted by using dilutions of the bioactive extract in the range of 1:450000, 1:200000, 1:100000, 1:50000 and 1:25000 times for assessing non-toxic nature of the dye upon survival of eukaryotic and prokaryotic cells.

The present invention provides a method for extraction, partial purification and characterization of a natural non-polar nontoxic cell membrane permeant multiple fluorescent dye. It further provides compositions at which the dye can detect live eukaryotic and prokaryotic cells without killing them and it comprises of:

collection of the material from field and maintenance in the laboratory conditions,

extraction of the pigment from the 70% alcoholic extract of the ovary of the echinoderm sea cucumber

Holothuria scabra , and partial purification of the dye.

Testing of biological activities.

The bioactive extract of the invention is obtained from 70% alcoholic extract of the ovarian tissue of marine sea-cucumber Holothuria scabra . This extract is useful as a natural fluorescent dye and has the following characteristics:

1) no decolorization by a reducing agent,

2) not a synthetic compound,

3) crude extract of the dye is yellowish orange in color,

4) the dye has two steps of its extraction from the ovarian cells i.e. at step-1 the alcoholic solution is extracted and left to evaporate and step-2, solvent ether is added to the dried mass and filtered through Whatmann filter 1.

5) it produces dye solution containing partially purified fluorophore.

6) the dye solution is bright orange in color.

7) under tube light it emits variety of colors of the visible light spectrum.

8) the pigment is insoluble in water and alcohol.

9) the pure dye pigment is soluble in solvent ether, the further dilutions can be made by following the procedures given.

10) is a non-polar dye,

11) has pH of about 7,

12) absence of a reducable group,

13) the fluorophore is associated with the protein which is removed when heated and coagulated,

14) dye in solution emits six different colored fluorescence at 3 different wavelengths of the UV and visible ranges of the fluorescent cubes of an epifluorescence microscope, depending upon whether it is the dye solution alone or the cells on which it has attached.

15) fluorescence blue color emission occur in the 450 nm-470 nm range when excited under ultra violet cube WU-330 nm-385 nm excitation range,

16) fluorescence yellowish green color emission occurs in the 510 nm-570 nm range when excited under WB cube of 450 nm-480 nm excitation range,

17) fluorescence orange color emission occurs in the 610 nm-650 nm range when excited under WG cube of 510 nm-550 nm excitation range,

18) the dye emits hues of yellowish grays under the ordinary transmitted light bulb of the epifluorescence microscope when seen under 100×oil immersion objective,

19) the dye emitted these fluorescence colors even at a dilution range of 1:400000 to 1:900,000 times and above.

20) the fluorescence of the extract persisted even after at least 1 year at the 4 degree centigrade

21) the fluorescence of the dye is highly photostable and does not get deteriorated by long exposures to direct light once the cells are stained even at the room temperature.

22) the fluorescence of the dye does not change even when frozen at minus 20 degree centigrade, a temperature at which the molecules are unable to attain the energy necessary for activation like in extracts from luminescent organisms.

23) The dye is nontoxic to the living cells of eukaryotes.

24) The dye is also nontoxic to the prokaryotes ( E.coli )

25) The dye is cell membrane penmeant

26) The dye is cell membrane impermeable to dead animal cells.

27) The dye is cell membrane impermeable to dead E.coli bacteria.

28) The dye is a non-degradable stain of the cell membranes.

The physical and other characteristics of the dye may be assessed by the following step:

a. color and solubility of the dye,

b. photostability

c. photobleaching

d. nontoxicity

e. selective staining of cell membranes

f. Physical checking of emission under a UV transilluminator 260-280 nm range,

g. Preparation of slide with live oyster eggs and sperms

h. Preparation of slides of live bacteria

i. Preparation of the fixed cells slides by air dried method,

j. Staining of slides with the dye,

k. Keeping controls for each experiment without adding dye.

l. Epifluorescent microscopic screening of the live eukaryotic cells slides under fluorochrome cubes WU, WB, WG and Bright field,

m. Epifluorescent microscopic screening of the fixed eukaryotic cells under fluorochrome cubes WU, WB, WG and Bright field,

n. Epifluorescent microscopic screening of the dead eukaryotic cells under fluorochrome cubes WU, WB, WG and Bright field,

o. Epifluorescent microscopic screening of the live bacterial cells under fluorochrome cubes WU, WB, WG and Bright field,

p. Epifluorescent microscopic screening of the dead bacterial cells under fluorochrome cubes WU, WB, WG and Bright field,

q. Epifluorescent microscopic screening of the live control cells without the dye under fluorochrome cubes WU, WB, WG and Bright field,

r. Microphotography of emitted fluorescence in the areas of slides without any cells,

s. Microphotography of emitted fluorescence of the cytogenetic slides under fluorochrome cubes WU, WB, WG and Bright field, and

t. Checking of wavelength ranges of the fluorescent hues of emission and wavelength ranges of the excitation ranges of fluorochrome cubes with the dye

u. Checking of wavelength ranges of the fluorescent hues of emission and wavelength ranges of the excitation ranges of fluorochrome cubes with the cells stained with the dye

v. Checking for cell membrane permeability of plasma membrane, cytoplasm, nuclear membrane, nucleoplasm and chromosomes.

Thus the invention provides a non-polar natural fluorescent dye of marine animal origin which emits six different colored fluorescence in the hues of blue, yellow and orangish red when excited with three different ranges of wavelengths in the UV and visible light spectral cubes of an epifluorescence microscope. The range of emissions of the dye solution and that of cells stained with the dye differs. The invention further relates to the epifluorescence microscopy of eukaryotic and prokaryotic live, fixed and dead cell preparations by using this dye as the epifluorescent microscopic stain. This dye could be used in making non-radioactive labeling kits for molecular diagnostics by fluorescent in situ hybridization in various molecular, biomedical and engineering sciences.

In an embodiment the source of the dye is an invertebrate marine animal belonging to SubKingdom: Metazoa, Phylum Echinodermata; subphylum: Eleutherozoa, Class Holothuroidea. Name: Holothuria scabra

In yet another embodiment the Holothuria scabra is selected from the group comprising of sea cucumbers and widely distributed in the shores, shallow waters, deep waters all over the world particularly Indo-Pacific. The nearest well-known relatives of sea cucumber are the sea urchins and starfishes etc.

In yet another embodiment Holothuria scabra is dissected, its ovaries are separated and weighed. In step 1, to 1 mg of ovarian tissue by wet weight 3 ml×3 times of 70% alcohol is added. This is called 70% alcoholic extract of ovarian tissue.

In yet another embodiment in step 2, heating the solution coagulates the protein and alcohol is evaporated. The dried mass dissolves only in non-polar solvent ether.

In yet another embodiment, the colored solution is partially purified by filtering through Whattman No. 1 filter paper.

In yet another embodiment the vial with screw cap carrying the solution of the dye is labeled as “non-polar dye solution” and stored in cold room at 4° centigrade.

In yet another embodiment, the color of the dye solution is noted with naked eyes and tube light.

In yet another embodiment, the dye is found to be soluble in ether. The further dilutions for experiments can be made following given procedures.

In yet another embodiment, the photostability of the dye at the room temperature in the solution and on the stained cells is noted. It showed that the dye is non-degradable both at the room temperature and also once it attaches to the cell membranes.

In yet another embodiment test for electric charge of the Dye by electrophoresis is performed, the yellow spot showed non-polar behaviour and does not move towards any pole.

In yet another embodiment, the pigment is a dye as it is giving a color to the filter paper and staining the cell membranes.

In yet another embodiment, the dye has a pH of 7.0.

In yet another embodiment 1 ml of the dye solution of 70% alcoholic extract from which the present dye is isolated was taken and 0.2 gms of di thio erythritol was incorporated. The solution does not get decolorized. It showed that the reducible group is absent in the coloring part of the solution.

In yet another embodiment 9 ml of the 70% alcoholic extract from which the present dye is isolated was subjected to heating in a water bath at 100-degree Centigrade. Coagulation was observed. Which confirmed the presence of protein in the step 1 solution of the dye.

In yet another embodiment, after removal of the protein from the starting material, the colored part gets separated and dissolves only in ether.

In yet another embodiment, the alcoholic extract was subjected to Anthrone test (Ref) by using 4 ml of sulfuric acid and Anthrone reagent. 1 ml of Water 4 ml of conc. sulfuric acid and Anthrone reagent was kept as a blank. The blank was faintly green after 5 minutes whereas the extract was turned bright green after 5 minutes. The test proved that the carbohydrate is present in the alcoholic extract.

The fluorescence activity of the dye solution is due to a colored component that includes non-polar fluorophore attached to a negatively charged protein, which gets easily separated when the protein is coagulated.

In yet another embodiment nontoxicity test of the dye on eukaryotic cell survival was performed.

The dye was tested for cytotoxicity upon the oyster sperms. The survival of the sperms in the experimental set ups was taken as a parameter for showing nontoxicity. Male gonads of an oyster were removed and sperms were released in 100% seawater. These were filtered through muscline cloth to remove any debris. 1 mililiter (ml) of the sperm solution was Oaken and different concentrations (1 μl, 2 μl, 3 μl, 4μl and 5 μl) of the Dye solutions were added. At every half an hour the observations of survival of the sperms were made under a microscope. The experiments were continued for 24 hours. The Controls were maintained without addition of Dye. It was seen that there was no effect upon the survival rates of sperms with addition of the dye. This proved nontoxic nature of the dye.

In yet another embodiment nontoxicity test of the dye was performed upon survival of prokaryotes. The extract was tested for cytotoxicity upon gram negative E.coli bacteria by observing their survival or mortality. A drop of the live E.coli bacteria in water (50 μl) was placed on a microscopic slide. To this was added 0.5 μl-1.0 μl of the ether extract. The mixture was mixed using stirring needle. The slide was sealed so as to save it from evaporation. It was seen under the microscope that the bacteria remained alive for 24 hours till they remained in solution. They died if the solution got dried. The control experiments were performed. This proved that the dye is nontoxic to the bacteria.

In yet another embodiment, the bacteria do not show agglutination behavior. In another embodiment, the oyster eggs, sperms do not show agglutination behavior.

The applicants studied the nature of the dye and found that it gave multicolored emissions at different wavelengths of excitations, which are comparable to the fluorochrome microscopic stains already in the market. The blue colored fluorescence of the present dye is comparable to the emission of same color by DAPI fluorochrome at the same wavelength excitation, used as components of the non-radioactive labeling kits of biochemistry, cell biology, immunochemistry, and molecular biology. The yellow colored fluorescence of the said dye in the visible range is comparable to the same colored emissions of auramine used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

The yellow colored fluorescence of the said dye in the visible range is comparable to the same colored emissions of FITC used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

The orange colored fluorescent emission is comparable to the orange fluorescence color of Propidium Iodide fluorochrome used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

The orange colored fluorescent emission is comparable to the orange fluorescence color of TRITC fluorochrorrie used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

The dye is stable at the room temperature and has a long shelf life. The molecular and radioactive kits of the said dye can be exported at the room temperatures. The dye has characteristics of at least one hundred and twenty three different fluorochromes namely DAPI, Hoechest 33258, Hoechest 33342, FITC, acridine orange, auramine, Rhodamine, TRITC, and propidium iodide etc., which are now in the market (Bitplane products). The dye, under ordinary light of microscope the hues of grays produce a phase contrast effect which is useful in rapid screening of cytogentical, cytological, and histochemical slides and save expenses on the extra phase contrast accessory component of microscope. The fluorescence color emissions follow Stoke's law of fluorescence.

In yet another embodiment the epifluorescence microscopic studies are made by using this dye as a stain in the dilutions of above 1:400000 and recording emissions of light when excited by different cubes and compared the color hues with the known fluorochromes.

In yet another embodiment the screening was done using excitations of UV light and visible light spectra by WU, WB, WG and BF cubes of the Olympus reflected light.

In yet another embodiment WU cube's wavelength range is 330 nm-385 nm.

In yet another embodiment WB cube's wavelength range is 450 nm-480 nm.

In yet another embodiment WG cube's wavelength range is 510 nm-550 nm.

In yet another embodiment BF is for the bright field where an ordinary tungsten bulb delivers light.

In yet another embodiment, the emission ranges of the dye at different excitation ranges were found out. The background of the eggs in the epifluorescence microscopy photos shows the emission color of the dye.

In yet another embodiment it was seen that excitation with the WU 330 nm-385 nm range emitted fluorescence in the 450 nm-470 nm range.

In yet another embodiment Excitation with the WB filter having spectral range of 450 nm-480 nm emitted fluorescence in the 510-nm-570 nm range.

In yet another embodiment, the excitation with the WG filter having spectral range of 510 nm-550 nm emitted fluorescence in the 610-nm-650 nm range.

In yet another embodiment With BF the shades of yellowish grays were seen.

In yet another embodiment, the emission ranges of the dye after staining to the cell membranes at different excitation ranges were found out.

In yet another embodiment, the dye was used as fluorescence microscopic stain on the dead, live and fixed eggs of the oyster. The slides were screened under a epifluorescence microscope. It was noticed that the dead cells do not take up dye and shows no fluorescence.

In yet another embodiment, the dye was used as fluorescence microscopic stain on the live eggs of the oyster. The slides were screened under a epifluorescence microscope. It was noticed that the live cells showed fluorescence. The excitation spectral range and the emitted fluorescence strictly followed the Stoke's law. These ranges were different from the emission ranges of the dye, which represents the background of the fluorescing cell.

In yet another embodiment the dye was used as fluorescence microscopic stain on the fixed eggs of the oyster in 3:1 ethanol and acetic acid fixative. The slides were screened under a epifluorescence microscope. It was noticed that the fixed cells showed fluorescence. The excitation spectral range and the emitted fluorescence strictly followed the Stoke's law. These ranges were different from the emission ranges of the dye, which represents the background of the fluorescing cell.

In yet another embodiment excitation with the WU 330 nm-385 nm range emitted fluorescence in the 470nm-500 nm range in the cells.

In yet another embodiment excitation with the WB filter having spectral range of 450 nm-480 nm emitted fluorescence in the 570 nm-610 nm range.

In yet another embodiment, the excitation with the WG filter having spectral range of 510 nm-550 nm emitted fluorescence in the 610 nm-650 nm range.

In yet another embodiment the epifluorescent microscopic screening of the dead eggs under Bright Field emitted light in full white range of the visible spectra and depending upon the density of the cell ingredients gave hues of yellowish grays like a phase contrast effect.

In yet another embodiment the epifluorescent microscopic screening of the live eggs under Bright Field emitted light in full white range of the visible spectra and depending upon the density of the cell ingredients gave hues of yellowish grays like a phase contrast effect.

In yet another embodiment the epifluorescent microscopic screening of the fixed eggs (3:1 ethanol:acetic acid fixative) under Bright Field emitted light in full white range of the visible spectra and depending upon the density of the cell ingredients gave hues of yellowish grays like a phase contrast effect.

In yet another embodiment, the dye was used as microscopical stain for the E.coli . One loop of live E.coli bacteria was placed in 50 microliter of water on a microscopic slide and mixed. To this was added 0.5-1 microlitre (1 μl) of the dye solution towards outskirt of the bacterial suspension drop. The ether in the extract was allowed to evaporate by leaving the slide on bench for 4-5 sec. Both the drops were then mixed and a coverslip was placed on the sample and immediately sealed. Similarly a control preparation of bacterial suspension in water without dye was made.

In yet another embodiment both the slides were screened under oil immersion objective of a epifluorescence microscope (100×objective, 10×eye lens) for checking fluorescence. It was noticed that the dead cells don't take up dye and shows no fluorescence.

In yet another embodiment the live bacterial cells showed fluorescence. The excitation spectral range and the emitted fluorescence wavelengths strictly followed the Stoke's law. These were different from the dye solution and was as given below:

In yet another embodiment excitation with the WU 330-nm-385 nm range emitted fluorescence in the 470 nm-500 nm ranges.

In yet another embodiment Excitation with the WB filter having spectral range of 450 nm-480 nm emitted fluorescence in the 570-nm-610 nm range.

In yet another embodiment, the excitation with the WG filter having spectral range of 510 nm-550 nm emitted fluorescence in the 610-nm-650 nm range.

In yet another embodiment, the control E.coli without any dye also showed no fluorescence.

In yet another embodiment microphotography of the slides with the dye used as epifluorescence microscopy stain was done.

In yet another embodiment The microphotography of emitted fluorescence in the areas of slides with cells and the surrounding background which represented the emissions of colors only due to dye was done, under WU 330 nm-385 nm range, with Kodak film of 400 ASA speed with an exposure time varying from 50 to 60 seconds.

In yet another embodiment the microphotography of emitted fluorescence in the areas of slides with cells and the surrounding background which represented the emissions of colors only due to dye was done, under WB 450 nm-480 nm range, range, with Kodak film of 400 ASA speed with an exposure time varying from 50 to 60 seconds.

In yet another embodiment the microphotography of emitted fluorescence in the areas of slides with cells and the surrounding background which represented the emissions of colors only due to dye was done, under WB 510 nm-550 nm range, with Kodak film of 400 ASA speed with an exposure time varying from 50 to 60 seconds.

In yet another embodiment the microphotography of emitted fluorescence in the areas of slides with cells and the surrounding background which represented the emissions of colors only due to dye was done, under Bright field with Kodak film of 400 ASA speed with an exposure time varying from 50 to 60 seconds.

In yet another embodiment permeation of dye in the Cell membranes was found out. The unfertilized, fertilized eggs and larvae of oysters were stained with the dye and egg suspension ratio of 1:50 microliter and screened under a fluorescent microscope. It was seen that the fluorescence was noticeable in the plasma membrane, nuclear envelope and chromatin. Though the wavelength ranges of emissions were the same and the colors were the hues of the same shade, there was a noticeable demarcation of boundaries of these parts of the cell. This proved that the dye is permeable through the live and fixed cell membranes of egg plasma membrane, cytoplasm, nuclear membrane, nucleoplasm and chromatin.

In yet another embodiment, the absence of fluorescence of these parts of the cell in the dead cells showed that dye is irnpermeant to dead cell membranes.

Different stains are used for different excitation cubes of the fluorescent microscope. For example DAPI (DNA staining, emits blue color), Fluorescein-dUTP; Hoechest 33258, 33342 are seen under excitation with 330 nm-385 nm excitation cubes; FITC, Acridine Orange (for DNA, RNA emits greenish/yellowish hues), Auramine under 450 nm-480 nm excitation cube and Rhodamine, TRITC and Propidium iodide (DNA, emits orange hues) under 510 nm-550 nm excitation cube.

In an embodiment to this epifluorescence putting a drop of the diluted extract and excitation with the WU filter having spectral range of 330-385 nm wavelengths does microscopic screening of the cytological slides.

In another embodiment epifluorescence microscopic screening of the cytological slides is done by putting a drop of the extract and excitation with the WB filter having spectral range of 450 nm-480 nm wavelengths.

In another embodiment epifluorescence microscopic screening of the cytological slides is done by putting a drop of the extract and excitation with the WG filter having spectral range of 510 nm-550 nm wavelengths.

In yet another embodiment epifluorescent microscopic screening of the cytological slides under Bright Field objective using this dye by transmitted light.

In yet another embodiment epifluorescence microscopic screening of the cytological slides stained with the dye is done by observing hues of the fluorescence color emitted by the respective excitations.

In another embodiment the excitation with the WU 330 nm-385 nm range emitted fluorescence is in the 470 nm-500 nm range.

In another embodiment, the excitation with the WB filter having spectral range of 450 nm-480 nm emitted fluorescence in the 570 nm-610 nm range.

In yet another embodiment the excitation with the WG filter having spectral range of 510 nm-550 nm emitted fluorescence in the 610 nm-650 nm range.

In another embodiment epifluorescent microscopic screening of the cytological slides under Bright Field by using transmitted light emitted light in full white range of the visible spectra depending upon the density of the cell ingredients and giving a phase contrast effect.

In still another embodiment, the dye is diluted in 70% ethyl alcohol 1:9000 times and vaporized and the dried matter is again dissolved in 3 ml ether by repeating dissolution in the same amount of ether three times and further mixed in water to 1:50 time which means total dilution of the pigment is above 1:400000 times which gives fluorescence of six colors at three different wavelengths.

In yet another embodiment the invention provides a bioactive composition containing an extract obtained from the marine sea-cucumber Holothuria scabra in the ratio of 1:400000 to obtain fluorescence of six colors at three different wavelengths and a phase contrast effect under transmitted light.

In an embodiment, the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful in the preparation of coating compositions and inks.

In another embodiment, the invention provides composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful in detection of leaks.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful in undersea probes.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful as a fluorescent probe in situ hybridization kits for molecular diagnosis.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful as a component of non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry and molecular biology.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful in immuno fluorescent detections.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful as a counterstain of DIG-labeled oliogonucleotide probes and anti-DIG Fab-fragments.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful in single and multiple cell quantitative fluorescence in flowcytometry.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful as fluorochrome stains for epifluorescence microscopy.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful for a quick check of biocontamination in the health food industry, cosmetic industry, pharmaceutical and chemical industries.

In yet another embodiment the invention provides a composition comprising a bioactive extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful for rapid estimations of biocontaminants in laboratory cultures.

In yet another embodiment the invention provides a composition comprising a bio active extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful for a rapid check of biopollutants under field conditions.

In yet another embodiment the invention provides a composition comprising a bio active extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful in microbial kits.

In yet another embodiment the invention provides a composition comprising a bio active extract obtained from the marine sea-cucumber Holothuria scabra together with conventional additives and useful as a natural colorant.

In yet another embodiment the dye solution contains a fluorophore which can be conjugated with proteins and other bio molecules for making customer oriented dye compositions.

DESCRIPTION OF THE TABLES

TABLE-1 The Emissions of the different colored fluorescence of the fluorescent dye when excited with different wavelength fluorescent filter cubes of the Olympus epifluorescence microscope with dye solution and when attached to cell membranes of the prokaryotic cells.

TABLE-2 The Emissions of the different colored fluorescence of the fluorescent dye when excited with different wavelength fluorescent filter cubes of the Olympus epifluorescence microscope with dye solution and when attached to cell membranes of the eukaryotic cells.

Table-3 Table showing various commercially important features of the three natural fluorescent dyes extracted from the sea cucumber of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The file of this patent contains at least one drawing executed in color. Copies of this patent with color drawings will be provided by the Patent and Trademark Office upon request and payment of the necessary fee.

FIG. 1 Black and white figure of epifluorescence microscopy results of green color fluorescent emissions of the dye and yellow colored emissions of the bacterial cells where dye has attached (arrow) when the dye was excited with WB filter cube of Olympus BX-60 microscope having excitation range of 450-480 nm.

FIG. 1 a Colored photograph of FIG. 1 .

FIG. 2 Black and white figure of epifluorescence microscopy results of dark red color fluorescent emissions of the dye and orange colored emissions of the bacterial cells where dye has attached (arrow) when the dye was excited with WG filter cube of Olympus BX-60 microscope having excitation range of 510 nm-550 nm nm.

FIG. 2 a Colored photograph of FIG. 2 .

FIG. 3 Black and white figure of epifluorescence microscopy results of dead bacteria showing no fluorescence.

FIG. 3 a Colored photograph of the same under WG filter cube of Olympus BX-60 microscope having excitation range of 510 nm-550 nm.

FIG. 4 Black and white figure of epifluorescence microscopy results of dark red color fluorescent emissions of the dye and orange colored emissions of the oyster egg cell where dye has attached when the dye was excited with WG filter cube of Olympus BX-60 microscope having excitation range of 510 nm-550 nm nm. The nuclear envelope and chromatin is seen.

FIG. 4 a Colored photograph of FIG. 4 .

FIG. 5 Black and white figure of epifluorescence microscopy results of green color fluorescent emissions of the dye and yellow colored emissions of the live egg cells where dye has permeated (arrow) when the dye was excited with WB filter cube of Olympus BX-60 microscope having excitation range of 450-480 nm. The cell permeant nature of the dye showing egg membrane and nuclear envelope and the cytoplasm and nucleoplasm stained (arrows)

FIG. 5 a Colored photograph of FIG. 5 . The chromatin of sperm nucleus is also seen.

FIG. 6 Black and white figure of epifluorescence microscopy results of dark bluish green color fluorescent emissions of the dye and blue colored emissions of the live egg cells where dye has permeated (arrow) when the dye was excited with WU filter cube of Olympus BX-60 microscope having excitation range of 330 nm-385 nm. The cell permeant nature of the dye showing egg membrane and nuclear envelope and the cytoplasms and nucleoplasm stained.

FIG. 6 a Colored photograph of FIG. 6 . The chromatin inside the nucleus is also seen.

FIG. 7 Black and white figure of epifluorescence microscopy results of dark bluish green color fluorescent emissions of the dye and bright bluish white colored emissions of the oyster embryo cells 5 days after the permeation of the dye (arrow) when the dye was excited with WU filter cube of Olympus BX-60 microscope having excitation range of 330 nm-385 nm.

FIG. 7 a Colored photograph of FIG. 7 .

FIG. 8 Black and white figure of epifluorescence microscopy results of dark bluish green color fluorescent emissions of the dye and yellow colored emissions of the live oyster embryo cells 5 days after permeation of the dye (arrow) when the dye was excited with WB filter cube of Olympus BX-60 microscope having excitation range of 450-480 nm.

FIG. 8 a Colored photograph of FIG. 8 .

FIG. 9 Flow-chart.

This invention pertains to the process of extraction, partial purification and characterization of a New natural non-polar pigment which is fluorescent dye from an echinoderm (Holothuroidea: Holothuria scabra ) widely distributed along the central West Coast of India and the Indo-pacific regions of the world.

The invention further provides a novel fluorescent protein dye from the ovarian tissue of the animal which can be repeatedly extracted 3-4 times from the same tissue by storing in 70% ethyl alcohol under −4 degree Centigrade, thus saving over exploitation of natural resources.

The present invention also contemplates that the said dye has six colored fluorescent emissions at three different excitation wavelengths of UV and visible light spectra equivalent to emissions by six different fluorochromes (DAPI, FITC and PI) and the pycobiliproteins and rhodamines currently used for multicolor fluorescent detentions. The dye actually covers the wavelength emission spectra of about one hundred and twenty three fluorochromes currently sold in the market for fluorescent microscopy probes. The stained cells show different color emissions at the same excitations but strictly follow stroke's law. Thus altogether at same excitations of olympus BX-60 microscope filters the dye emits 6 colors.

The dye is nontoxic to living E.coli bacteria and eukaryotic cells.

The dye permeates through the various cell constituents membranes and stains them fluroscently.

The dye is non-degradable once it is attached to cell membranes by staining them. The dye does not show agglutination of bacteria and anomal cells. The dye is a fluorophore in ether solution. The fluorciphore is conjugated to a protein in the 70% alcohol solution of ovarian tissue.

Thus, the dye can be commercialized as natural nontoxic cell permeant multiple fluorescent dye of epifluorescence microscopy for single, double and triple staining of chromosomes cells and tissues following simple protocols.

The present invention also contemplates the use of the dye in non-radioactive labeling of protein, DNA and RNA probes for fluorescent in situ hybridization applications in molecular biology.

Thus in a preferred mode of use the dye can be a component of molecular labeling and detection kits, most of which are imported and sold at high rates.

These labeling kits are widely sought after for molecular diagnostics using rapid molecular cytogenetic and microarrays techniques.

Yet another advantage of the dye is that its fluorescence is visible even in very dilute solutions (1:40000 to 400000) and above.

This property and the nontoxic Eco friendly nature of the dye can be utilized in life saving devices as a component of life jackets and to mark the location of crashed aircraft, life rafts and defense equipment for example rockets, leaking checks in the industries etc.

The invention would be useful for quantitative measure of fluorescence in flow cytometer for single and multiple cells.

The invention would be also advantageous in quick estimations of bio-contamination in natural and controlled environments like tissue cultures, pollution, and industrial contamination in health, food and cosmetic industries.

In another preferred mode of use the dye bottle if sealed properly has a long shelf life at the room temperature.

In another preferred mode of use the dye has a long shelf life at the room temperature once the cells are stained as checked by fluorescent microscopic analysis.

Another utility of the fluorescent dye is as a component of novel remote sensing devices and undersea probes where light wavelength sensitivity based data is required.

The invention is illustrated by the following examples, which should not be construed as limitations on the inventive scope of the invention in any manner.

EXAMPLES

The methods of isolation, partial purification, characterization of the dye and the details of the experiments performed to check non-polar, nontoxic, cell permeant, non-agglutination and multiple fluorescent effects of the dye by epifluorscence microscopy are disclosed:

Example 1

Collection of the Material

Material of the patent is a sea cucumber with following taxonomic details. Subkingdom: Metazoa; Phylum: Echinodermata; Sub-Phylum: Eleutherozoa; Class: Holothuroidea; Subclass: Aspidochirotacea; Order: Aspidochirota; Genus: Holothuria Species: scabra

The material was collected from the shores of central West Coast of India during a low tide. The animals were brought to the laboratory and maintained in glass tanks containing seawater of salinity 30-32 per par (30% 0 ) till further use.

Example 2

Extraction of the Dye

Extraction of the dye is a two step process. First an alcoholic extract is made and second the alcohol is evaporated and the fluorophore is separated and dissolved in solvent ether as follows:

Step 1: The animals were first washed with tap water and then with Milliq water (ultra pure water). The body was cut open with the sharp scissors and the female gonads were identified and removed. The color of the ovaries varied from yellow to orange. 1 milligram (1 mg) of the ovarian tissue is weighed and 70% ethyl alcohol was added to it in the ratio of 1:3 (weight by volume ratio). Yellowish orange colored pigment came out. The dye solution was decanted. To the remaining tissue again 70% ethyl alcohol was added and colored solution removed. These steps were repeated three times for extraction of the pigment without homogenizing the tissue of the ovary. The extract was filtered through Whattman No. 1 filter paper. The extract was was stores in a vial with screw cap at 4° C. and termed as “Stock dye solution”. The extract carrying both light-yellow and orange colored pigments from the ovarian tissue were characterized by the following methods. The properties were found the same. 1 mg ovarian tissue: 3 ml of 70% ethyl alcohol (3 times) i.e. 1 mg of pigment in 9 ml or 9000 microliter of alcohol.

Step 2: 15 ml of 70% alcoholic dye solution was taken, heated to coagulate the proteins and evaporated slowly to dryness in a water bath at 80° centigrade. The dried material was not soluble in water and alcohol. It was soluble in ether. Ether was added to the dried material and allowed to stand at the room temperature for 15 minutes. The coloring portion got dissolved. It was then filtered by a Whattman no 1 filter paper to obtain a clear yellow colored solution, which was labeled as “Non-polar fluorescent dye”.

Example 3

Physical Characteristics of the Dye

Color and Solubility

The said Dye solution is orange in color with the naked eye. In the daylight/tube light it gives varied colors emissions. The dye is insoluble in water but is soluble in non-polar solvent ether. Hence it is a non-polar dye. The dye has pH of 7.0.

Example 4

The said extract was subjected to paper electrophoresis. A whattman No.1 filter paper was soaked in phosphate buffer (0.1 M ) pH 7 and placed in an electrophoresis chamber. Both the electrodes were immersed in phosphate buffer. A spot was made with 5 microlitre (μl) of the dye subjected to paper electrophoresis at 40 volts. The yellow spot does not move toward to any side. Further, it is getting dissolved only in the non-polar solvent ether. Since the dye is dissolving only in the ether, it is a non-polar dye.

Example 5

Photostability

The ether extract of the dye is stable at room temperature. However to safeguard from evaporation the ether solution of the dye is kept at a cool place. Once the cells are labeled with the dye the fluorescence remains for months together at the room temperature.

Example 6

Test for Electric Charge of the Dye by Electrophoresis

The said extract was subjected to paper electrophoresis. A whattman No. 1 filter paper was soaked in phosphate buffer (0.1 M) pH 7 and placed in an electrophoresis chamber. Both the electrodes were immersed in phosphate buffer. A spot was made with 5 microlitre (μl ) of the of the dye subjected to paper electrophoresis at 40 volts. The yellow spot does not move toward to any side.

However, the 70% alcohol solution of isolation of phase 1 when tried, the colored spot moved towards positive pole. Which indicates that the non-polar pigment of the present dye in the phase 1 alcoholic extract of the ovarian tissue is attached to some negative protein. Chemical and HPLC analysis found the presence of proteins and carbohydrates in the alcoholic extract.

Example 7

Chemical Properties of Dye

1 ml of the dye solution, which is the alcoholic ovarian extract, was taken and 0.2 grams of di thio erythritol was incorporated. The solution does not get decolorized. It showed that the coloring part of the fluorescent dye does not contain a reducible group.

Example 8

Test of Non-proteinaceous Nature of the Dye

5 ml of the step 1 extract was subjected to heating in a water bath at 100 degree centigrade. Coagulation was observed in the alcoholic extract. This confirmed presence of protein in the starting alcoholic extract, however the protein was removed b coagulation. The colored solution came from the dried matter by dissolving it in ether. Since, the protein part has been removed the dye is said to be of non-proteinaceous nature.

Example 9

Absence of Agglutination of Bioactivity

One loop of live E. coli bacteria was placed in 50 microliter of water on a microscopic slide and mixed. To this was added 1 microlitre (1 μl) of the dye solution. The alcohol was allowed to evaporate by leaving the slide on bench for 10-15 sec. A coverslip was then placed on the preparation of bacteria and sealed. Similarly a control preparation of bacteria was made without any dye.

Both the slides were screened under oil immersion objective of an epifluorescence microscope (100×objective, 10×eye lens) for checking the agglutination bioactivity and the fluorescence under WU, WB, WG and BF. It was seen that the bacteria did not show any clump formation ( FIGS. 10 , 10 a ).

The agglutination behavior was, however, noticed in the 70% alcoholic solution removed from the ovary tissue in phase 1 of isolation. But the protein was removed in the second phase of isolation and the present dye solution was of non-proteinaceous nature.

The absence of the tendency of cells to make aggregations in the presence of the present dye solution indicated that it does not contain a lectin like glycoprotein any more.

Example 10

Agglutination Bioactivity Test with Eukaryotic Sperms

One milliliter solution of oyster sperms (100 microliter) was placed in the cavity of a sedgewick counter used for phytoplankton counts. 1 microliter (1 μl) of dye solution was added. The slide was screened under 40×objective of a microscope with 10×eye lens. It was observed that the sperms did not make clumps, which confirmed lacking of lectin like activity of the dye.

Example 11

Test for Fluorophore and Protein Association in Phase 1 Material of 70% Alcoholic Solution but Absent in the Present Dye Phase 2 Isolation

As mentioned in examples 4and 6, the fluorophore shows non-polar behavior. But it appears that in the 70% alcoholic solution of ovarian tissue of isolation phase 1 the colored spot moves towards positive pole during paper electrophoresis. It may be bound in that phase to some component, which is negatively charged. The HPLC data of the 70% alcoholic solution detected only proteins and carbohydrates. As carbohydrates do not have an electric charge, it suggested that the colored component of the present dye in phase 1 (70% alcoholic solution) be attached to some protein, which is negatively charged. However, in isolation phase 2, which produces the present dye, it gets separated from the protein on coagulation by heating. It is the solution of phase 2 dye, which forms the present nonpolar dye solution.

Example 12

Method of Using the Non Polar Dye in Experiments

The dye is soluble in ether so a special method is adopted for of adding dye to the experimental animals. Live cells are taken on a clean slide. To this is added a measured amount of ultra pure/seawater depending upon the media in which the cells are cultured and remain alive in controls. The measured amount of the dye is placed on outer skirt of the drop and allowed to evaporate for 2-3 seconds. The solution is then mixed with tip of an eppendorf. A coverslip is immediately placed on the sample and sealed. The slides are labeled and the cells are viewed under an epifluorescence microscope.

Example 13

Nontoxicity Test of the Dye on Eukaryotic Cells

The extract was tested for nontoxicity upon the oyster sperms. The survival of the sperms in the experimental set ups was taken as a parameter for showing nontoxicity Male gonads of an oyster were removed and sperms were released in 100% seawater. These were filtered through a musline cloth to remove any debris. 1 mililiter (ml) of the sperm solution was taken and different concentrations (1 μl, 2 μl, 3 μl, 4 μl and 5 μl) of the Dye solutions were added. At every half an hour the observations of survival of the sperms were made under a microscope. The experiments were continued for 24 hours. The Controls were maintained without addition of Dye. It was seen that there was no harmful effect upon the survival of sperms with the addition of the dye. This proved nontoxic nature of the dye to estuarine and marine animal cells.

Example 14

Nontoxicity Test of the Dye on Prokaryoles

The extract was tested for toxicity upon gram negative E.coli bacteria by observing their survival/mortality. Live E.coli bacteria were taken on a clean slide. To this was added 25 μl ultra pure water. 1 μl of the dye is placed on outer skirt of the drop and allowed to evaporate for 2-3 seconds. The solution is then mixed with tip of an eppendorf. A cover slip is immediately placed on the sample and sealed. The slides are labeled and the cells are viewed under an epifluorescence microscope FIGS. 1 , 1 a , 2 and 2 a ). The dead bacteria do not show any fluorescence (FIGS. 3 , 3 a ).

Example 15

Dye Permeability Test in Oyster Eggs

The unfertilized, fertilized eggs and larvae of oysters were stained with the dye and egg suspension ratio of 1:50 microliter and screened under a fluorescent microscope. It was seen that the fluorescence was noticeable in the plasma membrane, nuclear envelop and chromatin. Though the wavelength ranges of emissions were the same and the colors were the hues of the same shade, there was a noticeable demarcation of boundaries of these parts of the cell (FIGS. 4 , 4 a , 5 , 5 a, and 6 , 6 a ). This proved that the dye is permeable through the live and fixed cell membranes of egg plasma membrane, cytoplasm, nuclear membrane, nucleoplasm and chromatin. The absence of fluorescence of these parts of the cell in the dead cells showed that dye is impermeable to dead cell membranes.

Example 16

Detection of Live and Dead Bacteria in Cultures

A drop of the live E.coli bacteria in water (25 μl) was placed on a microscopic slide. To this was added 1 μl of the dye. The slide was sealed temporarily so as to save it from evaporation. It was seen under the microscope that the bacteria gave fluorescence in all the filter excitation ranges like WU, WB and WG. The controls were kept with the live E.coli without the stain and the dead E.coli . In both the controls the bacteria did not show fluorescence. This showed that the dye could be used for sorting live and dead bacteria in cultures (FIGS. 3 , 3 a )

Example 17

Dye Useful for Checking Results of Cytotoxicity Bioassays

The quality of showing fluorescence in the live and fixed cells and not the dead cells is useful for checking cytotoxicity and antibacterial activity of various compounds by performing bioassays and checking the results with this dye.

Example 18

Dye Useful for Checking Bacterial Contamination

The quality of showing fluorescence in the live and fixed cells and not the dead cells is useful for checking contamination in the environmental and industrial samples where presence and absence of bacteria needs to be seen.

Example 19

Epifluorescence Microscopy of the Fluorophore

The epifluorescence microscopic studies are made by using this dye as a stain in the dilutions of 1:100 and recording emissions of light when excited by different cubes and compared the color hues with the known fluorochromes. It was noticed that the emissions were much stronger with the fluorophore though the shades of colors were the same. The screening was done using excitations of UV light and visible light spectra by WU, WB, WG and BF cubes of the Olympus reflected light. The details of cubes were as follows:

WU cube's wavelength range was 330 nm-385 nm.

WB cube's wavelength range was 450 nm-480 nm.

WG cube's wavelength range was 510 nm-550 nm.

BF is for the bright field where an ordinary tungsten bulb delivers light.

Example 20

The emission ranges of the dye at different excitation ranges were found out. It was seen that excitation with the WU 330 nm-385 nm range emitted fluorescence in the 450 nm-470 nm range. Excitation with the WB filter having spectral range of 450 nm-480 nm emitted fluorescence in the 510 nm-570 nm range. The excitation with the WG filter having spectral range of 510 nm-550 nm emitted fluorescence in the 610nm-650 nm range. With BF the shades of yellowish grays were seen.

Example 21

Fluorescence Emissions in the Oyster Cells

The dye was used as microscopical stain on the dead, live and fixed eggs of the oyster. The slides were screened under an epifluorescent microscope. It was noticed that the dead cells do not take up dye and shows no fluorescence. ( FIGS. 4 , 4 a, 5 , 5 a, 6 , 6 a, 7 , 7 a, 8 and 8 a ). The fluorescence was observed in the eggs even 5 days after the first use of the dye and leaving the slides it the room temperature.

The live and fixed cells showed fluorescence. The excitation spectral range and the emitted fluorescence strictly followed the Stoke's law. These were different from the dye solution and was as given below:

Excitation with the WU 330 nm-385 nm range emitted fluorescence in the 470 nm-500 nm range. Excitation with the WB filter having spectral range of 450 nm-480 nm emitted fluorescence in the 570 nm-610 nm range. The excitation with the WG filter having spectral range of 510 nm-550 nm emitted fluorescence in the 610 nm-650 nm range. The epifluorescent microscopic screening of the dead, live and fixed eggs under Bright Field by using transmitted light emitted light in full white range of the visible spectra and depending upon the density of the cell ingredients gave hues of gray a phase contrast like effect.

Example 22

Fluorescence Emissions in the E.Coli Cells

The dye was used as microscopical stain on the E.coli . The slides were screened under a epi fluorescent microscope. It was noticed that the dead cells do not take up dye and show no fluorescence. ( FIGS. 3 , 3 a ). The live cells showed fluorescence. The excitation spectral range and the emitted fluorescence strictly followed the Stoke's law. These were different from the dye solution and was as given below:

Excitation with the WU 330 nm-385 nm range emitted fluorescence in the 470 nm-500 nm range. Excitation with the WB filter having spectral range of 450 nm-480 nm emitted fluorescence in the 570 nm-610 nm range. The excitation with the WG filter having spectral range of 510 nm-550 nm emitted fluorescence in the 610 nm-650 nm range. The control E.coli without dye did not show any fluorescence.

Example 23

Microphotography of the Fluorescent Cells with the Dye used as Stain

The microphotography of emitted fluorescence in the areas of slides without cells and with specimen cells, under WU 330 nm-385 nm range, WB 450 nm-480 nm range, WG 510 nm-550 nm range and Bright field was done by Kodak film of 400 ASA speed with an exposure varying from 50 to 60 seconds.

Advantages Over the Present Marketed Dyes

1) The dye is non-radioactive as it is a dye from a natural source and not synthetic.

2) The dye is nontoxic to estuarine, marine animals and gram negative E.coli bacteria

3) The dye is cell membrane permeant and attaches itself to nuclear mebrane and chromatin also.

4) The dye is permeant to cytoplasm and nucleoplasm.

5) The dye is a non-polar fluorescent dye from a non-bioluminescent marine animal.

6) The dye is a partially purified fluorophore in solution.

7) This dye in its single form is equivalent to six synthetic fluorochromes which covers the major part of UV and visible light spectrum emission of fluorescent colors.

8) The dye can be used as a quick microscopic stain giving a phase contrast effect without any extra expenses on phase contrast accessory of a microscope and without any lengthy protocols of fixations and preservations of specimens, especially on the spot quality check of live samples.

9) Being non-degradable in quality of fluorescence at the room temperature, it does not require refrigeration while exporting the dye. The presently marketed fluorescent dyes are exported under refrigeration equivalent to −20 degree centigrade.

10) Being non-degradable in quality of fluorescence on stained cells for longer duration, it does not require refrigeration while exporting stained slides. The dye solution can be marketed at 4 degree centigrade. The presently marketed fluorescent dyes exported under refrigeration equivalent to −20 degree centigrade.

11) The dye has a pH in the range of 7.0 so in compositions the pH of the products will not change drastically.

12) The fluorophore can be conjuagetd with other biomolecules.

13) The dye is non-polar.

14) It is soluble in ether

15) The dye is non-degradable under natural conditions.

16) The dye is non-degradable under natural conditions and also once it gets attached to the cell membranes. This can be of immense value to study live cell functions, organelle structure, cell sorting and flowcytometry.

17) The dye solution is nontoxic to live bacteria and oyster eggs and sperms.

18) The nontoxic nature of the dye has the advantage that this can be made a dye component of kits dealing with analysis of live cells

19) The nontoxic nature of the dye has the advantage that this can be made a dye component of kits dealing in situ operational studies in oceanography.

20) The dye does not stain and do not show fluorescence on dead bacteria. This is useful in tissue culture for checking live and dead cells.

21) The dye being nontoxic to live cells can be useful in following up of cell lines.

22) The dye is cell membrane permeant in the live and fixed cells. This is a natural dye so has the advantage over the synthetic ones because it will be more ecofriendly.

23) The dye covers a wider range of emission wavelengths at selective excitations. This makes it a very acceptable component of dual emission dyes kits marketed presently for addition of a third emission color range.

24) The dye does not undergo photobleaching while screening under the microscope.

25) The dye does not show photobleaching once it stains the cells on slides. This makes it useful in histochemical studies.

26) The dye emitted these fluorescence colors even at a dilution range of 1:400000 to 1:900000 times

27) These multicolored emissions of the dye at different wavelengths of excitations are comparable to the fluorochrome microscopic stains already in the market.

28) The blue colored fluorescence of the present dye is comparable to the emission of same color by DAPI fluorochrome at the same wavelength excitation, used as components of the non-radioactive labeling kits of biochemistry, cell biology, immunochemistry, and molecular biology.

29) The blue colored fluorescence of the present dye is also comparable to the emission of color by Hoechest 33258 used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

30) The blue colored fluorescence of the present dye is also comparable to the emission of color by Hoechest 33342 fluorochrome at the same wavelength excitation used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

31) The yellow colored fluorescence of the said dye in the visible range is comparable to the same colored emissions of Acridine orange used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

32) The yellow colored fluorescence of the said dye in the visible range is comparable to the same colored emissions of auramine used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

33) The yellow colored fluorescence of the said dye in the visible range is comparable to the same colored emissions of FITC used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

34) The orange colored fluorescent emission is comparable to the orange fluorescence color of Propidiumr Iodide fluorochrome used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

35) The orange colored fluorescent emission is comparable to the orange fluorescence color of Rhodamine fluorochrome used as components of the non-radioactive labeling and (detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

36) The orange colored fluorescent emission is comparable to the orange fluorescence color of TRITC fluorochrome used as components of the non-radioactive labeling and detection kits of biochemistry, cell biology, immunochemistry, and molecular biology.

37) Unlike the synthetic commercial dyes used for the same purposes, the present dye is stable at the room temperature and has a long shelf life. Molecular non-radioactive kits of the said dye can be exported at the room temperatures.

38) The said single dye has characteristics of atleast one hundred and twenty three different fluorochromes (DAPI, Hoechest 33258, Hoechest 33342, FITC, acridine orange, auramine, Rhodamine, TRITC, and propidium iodide etc.) now in the market.

39) Under ordinary light of microscope the hues of grays produce a phase contrast effect which is useful in rapid screening of cytogentical, cytological, and histochemical slides and save expenses on the extra phase contrast accessory component of microscope. The fluorescence color emissions follow Stoke's law of fluorescence.

40) The microphotographs with Kodak film rolls show hues of the adjacent color emission wavelengths. Like when seen blue color fluorescence under the epifluorescence microscope in microphotograph the hues of green also comes.

41) The microphotographs with Kodak film rolls show hues of the adjacent color emission wavelengths. Like when seen yellow color fluorescence under the epifluorescence microscope in microphotograph the hues of green also comes.

42) The dye when seen orange fluorescence color under the epifluorescence microscope in microphotograph the hues of red also come.

43) The cytogenetic slides seen under all fluorescence gives a counterstain effect of cells with the background where no specimen but only dye is present.

44) The dye can be used in fluorescent colors in variety of paints, inks, and textiles.

45) The dye can be used in compositions of fluorescent dye for bleaching and brightening polymer.

46) The dye can be used in leak detection with a full spectrum fluorescent dye.

47) It can also be used in automated chemical metering system. It can also be used to mark the location of crashed aircraft, life crafts, and equipment for example rockets. Further it can be used in under sea probes.

48) The nontoxic and cell permeant nature of the dye can be used as a component of the non-radioactive labeling and detection kits of biochemistry, cell biology, mmunochemistry, and molecular biology for labeling of DNA, RNA, Proteins and enzymes., Immunofluorescent detections, Counterstain of DIG-labeled oliogonucleotide probes and Anti-DIG Fab-fragments, Single and multiple cell quantitative fluorescence in Flowcytometry., Fluorochrome stains for epifluorescence microscopy.

49) The dye can be used for a quick check of biocontamination in the health food industry, cosmetic industry, pharmaceutical and chemical industries, for rapid estimations of biocontaminants in laboratory cultures, for a rapid check of biopollutants under field conditions.

50) The dye can be used in compositions where a nontoxic dye is required.

51) The dye is environmentally friendly. It does not kill estuarine/marine animal larvae.

52) The dye can be used natural colorant. A bioactive composition of the marine dye in the ratio of 1:40000 to 1:400000 to obtain fluorescence of six colors at three different wavelengths and a phase contrast effect under transmitted light.

53) The dye being non-polar can easily be attached to variety of biomolecules.

54) It fits in the criterion of a good dye demand of the industry as it shows the different parts of the cell at one emission and at different emissions.

References cited (Referenced By)

Bandaranayake, W. M. and Des Rocher, A 1999 (Marine biology 133;163-169)

Bitplane products at (http://www.bitplane.ch/public/support/standard/fluorochrome.htm)

Boehringer Mannheim GmbH, Biochemica, Catalogue, printed in Germany, Chapter II. Non-radioactive In Situ Hybridization Application Manual. 1992)

Chalfie M “Green fluorescent protein” in 1: Photochem Photobiol October 62 (4): 651-656 (1995)

Chalfie et al. SCIENCE 263 (1994) 802-805. Proteins with other wavelengths in the range of red and yellow are produced by induced mutations in some aminoacids.

Debra K. Hobson and David S. Wales. “Green dyes”, Journal of the Society of Dyers and Colourists (JSDC), 114, 42-44, (1998).

Fradkov A F, Chen Y, Ding L, Barsova E V, Matz M V, Lukyanov S A “Novel fluorescent protein from Discosoma coral and its mutants possesses a unique far-red fluorescence. In 1:FEBS Lett August 18: 479 (3): 127-30. (2000).

George L. Clark, “Pigments” in Encyclopaedia of chemistry, 2 nd ed. Pages 833-835,1966.

Gurskaya N G, Fradkov A F, Terskikh A, Matz M V, Labas Y A, Martynov V I, Yanushevich Y G, Lukyanov K A, Lukyanov S A “GFP-like chromoproteins as a source of far-red fluorescent proteins” in 1: FEBS Lett October 19; 507 (1): 16-20 (2001).

Haughland R. P. Molecular probes. The Handbook of Fluorescent probes and Research Chemicals by Richard P. Haughland, 6 th edition Printed in the United States of America, 1996.

R. Norman Jones in The encycopaedia of chemistry, 2 nd edition,1966, Quote from pages 435-436

Wachter R M, Elsliger M A, Kallio K, Hanson G T, Remington S J. In 1: Structure Oct. 15, 1998; 6(10): 1267-77 described “Structural basis of spectral shifts in the yellow-emission variants of green fluorescent protein”.

Youvan D C, Michel-Beyerie M E “Structure and fluorescence mechanism of GFP in National Biotechnology October 1996 14 (10): 1219-20.

George L. Clark, “Fluorescence” in Encyclopaedia of chemistry, 2 nd ed. Page 435-436, 1966.

Kowalzick L; Ott A; Waldmann T; Suckow M; Ponnighaus J, M. Vogtlandklinikum Plauen (Elsevier Science B.V2000).

Matz M V, Fradkov A F, Labas Y A, Savitsky A P, Zaraisky A G, Markelov M L, Lukyanov S A. “Fluorescent proteins from nonbioluminescent Anthozoa species ”,1: Nat Biotechnolo December 1999: 17(10): 969-73.

Sepcic K, Turk T, Macek P “A fluorescent zoanthid pigment, parazoanthoxanthin A.” Toxicon, 36 (6): 937-940,1998.

Olympus Optical Co. Ltd, Tokyo Japan. Catalogue. “Instructions BX-FLA Reflected Light Fluorescence attachment” Page 16. 1999.

Shimomura, O, Johnson, F. H. and Saiga, Y “A novel reporter gene” Journal of cellular and comparative physiology, 59, 223-239, 1962.

Stainfile-Dyes A has given a Dye index of 264 dyes. Out of which 258 are synthetic and only six are natural dyes (http://members.pgonline.com/˜bryand/dyes/dyes.htm).

Wüerthner A. K. http://www.uniulm.de/uni/fak/natwis/oc2/ak wuert/publications.htm (referred from the internet).

Sigma-Aldrich “Biochemicals and reagents for life sciences research, 2000-2001 in their section immunochemicals of the catalogue under labeling reagents and cell linker labeling kits pp. 1454-1456. (web site www.sigma-aldrich.com)

U.S. Patents Documents
4,063,878	Dec. 20, 1977	Weeks, B. W.
4,452,822	Jun. 5, 1984	Shrikhande, Anil J
4,774,339	Sep. 27, 1988	Haughland, R. P et al.
4,762,701	Aug. 9, 1988	Horan et al.
4,783,401	Nov. 8, 1988	Horan et al.
4,859,584	Aug. 22, 1989	Horan et al.
5,248,782	Sep. 28, 1993	Haughland, R. P at al.
5,187,288	Feb. 16, 1993	Kang, H. C. at al.
5,274,113	Dec. 28, 1993	Kang, H. C et al
5,321,268	Jun. 14, 1994	Crosby David A and Ekstrom
		Philip A
5,304,493	Apr. 19, 1994	Nowak, A. V.
5,405,416	Apr. 11, 1995	Swinton; Robert J,
5,433,896	Jul. 18, 1995	Kang, H. C.
5,451,663	Sep. 19, 1995	Kang, H. C
5,770,205	Jun. 23, 1998	Collin, P. D
5,710,197	Jan. 20, 1998	Fischer et al.
5,876,762	Mar. 2, 1999	Collin, P. D
5,985,330	Nov. 16, 1999	Collin, P. D
5.858,761	Jan. 12, 1999	Tsubokura, et al.
5,902,749	May 11, 1999	Lichtwardt et al.
5,908,650	Jun. 1, 1999	Lenoble, et al
5,920,429	Jul., 6 1999	Burns et al.
5,935,808	Aug. 10, 1999	Hirschberg, et al
5,989,135	Nov. 23, 1999	Welch; David Emanuel
6,055,936	May 2, 2000	Collin; Peter Donald
6,056,162	May 2, 2000	Leighley; Kenneth C.
6,103,006	Aug. 15, 2000	DiPietro; Thomas C.
6,110,566	Aug. 29, 2000	White et al.
6,140,041	Oct. 31, 2000	LaClair; James J.
6,165,384	Dec. 26, 2000	Cooper et al.
6,180,154	Jan. 30, 2001	Wrolstad et al.
International patents:
EP0206718	Dec. 30, 1986	Cramer Randall J
IE901379	Jan. 30, 1991	Lee Linda G; Mize
		Patrick D
WO9010044	Jul. 7, 1990.	Swinton; Robert J
DE 4416476	Nov. 16, 1995	S. Beckmann et al.
WO 30679	Nov. 16, 1995	S. Beckmann et al.
DE 19611351	Mar. 22, 1996	K-H. Etzbach et al.
AU704112	Oct. 7, 1997	Burns David M; Pavelka
		Lee A
WO 35926	Oct. 2, 1997	K.-H. Etzbach et al.
DE 19648564 A1	May 28, 1998	C. Grund et al.
DE 19650958 A1	Jun. 10, 1998	C. Grund et al.
WO 98/23688	Jun. 4, 1998	C. Grund et al.
DE 19643097 A1	Apr. 23, 1998	F. Würthner et al.,
DE 19711445 A1	Sep. 24, 1998	F. Würthner et al.,
WO 41583	Sep. 24, 1998	F. Würthner et al.,
DE19755642	Jun. 24, 1999	Weimer Thomas DR.
WO9938919	Sep. 28, 1999	Laclair James J
WO0058406	Oct. 5, 2000.	Rosenblum Barnett B et
		al.
WO9938916	Aug. 15, 2000	DiPietro; Thomas C
WO9920688	Aug. 29, 2000	Pavelka Lee et al.
WO9920688	Aug. 29, 2000	White et al.

TABLE 1
The Emissions of the different colored fluorescence of the fluorescent
dye when excited with different wavelength fluorescent filter cubes of
the Olympus epifluorescence microscope with dye solution and when
attached to cell membranes of the prokaryotic cells.
Name of the
fluorescent					Emitted
cube as			Emission		Color
given in the	Excitation		range of		of the
catalogue	range	Emission	dye when		dye when
of Olympus	of the	range	attached to	Emitted	attached to
Optical	fluores-	of dye	Cell mem-	Color of	Cell mem-
Co. Ltd.	cent cube	solution	branes	dye	branes
M WU	330-	450 nm-	470 nm-	Blue	Blue
	385 nm	470	500
M WB	450-	510 nm-	570-	Green	Yellow
	480 nm	570 nm	610 nm
MWG	510-	610 nm-	610 nm-	Orangish	Orangish
	550 nm	650 nm	650 nm	Red	red
Bright field	Transmit-	White	White	Yellowish	Shades of
	ted light	light	light	gray	yellowish
					dark gray

TABLE 2
The Emissions of the different colored fluorescence of the
fluorescent dye when excited with different wavelength
fluorescent filter cubes of the Olympus
epifluorescence microscope with dye solution and when attached
to cell membranes of the eukaryotic cells.
Name of the
Fluorescent					Emitted
cube as			Emission		Color
given in the	Excitation		range of		of the
catalogue	range	Emission	dye when		dye when
of Olympus	of the	range	attached to	Emitted	attached to
Optical	fluores-	of dye	Cell mem-	Color of	Cell mem-
Co. Ltd.	cent cube	solution	branes	dye	branes
M WU	330-	450 nm-	470 nm-	Blue	Blue
	385 nm	470	500
M WB	450-	510 nm-	570-	Green	Yellow
	480 nm	570 nm	610 nm
MWG	510-	610 nm-	610 nm-	Orangish	Orangish
	550 nm	650 nm	650 nm	red	red
Bright field	Transmit-	White	White	Yellowish	Shades of
	ted light	light	light	gray	yellowish
					dark gray

TABLE 3
Table showing various commercially important features of the three natural fluorescent dyes extracted from
the sea cucumber Holothuria scabra by the present inventors. (The features are kept under different
headings as shown in column no. 1)
	Fluorescent Dye -(CSIR NF 140 2001)	Fluorescent Dye - (CSIR NF 152-2002)-	Fluorescent Dye - (CSIR NF 151-2002)
	patent filed	Another co-pending Application	Present Application
Heading/title	U.S. patent Ser. No. 09/820,654	U.S. patent Ser. No. — — —	U.S. patent Ser. No. — — —
Name of	Sea cucumber	Sea cucumber	Sea cucumber
Animal/species	Holothuria scabra	Holothuria scabra	Holothuria scabra
	(see example 1)	(see example 1)	(see example 1)
Bioactive	Pigment which is a fluorescent dye is	Pigment, which is a fluorescent dye, is	Pigment, which is a fluorescent dye, is
extract	extracted from skin of the animal with 50%	extracted from Live female gonads (ovarian	extracted from alcoholic extract of ovaries
	alcohol	tissue) of the animal with 70% alcohol and	by heating it and then dissolving in the
	(see example 2-5)	purified by filtration.	solvent either and purified by filtration.
		(see example 2)	(see example 2)
Chemical nature	Non proteinaceous	Proteinaceous	Non proteinaceous and is non-polar.
	(see example 7)	(see example 6, 8, 13)	(see example 2, 4, 8, 11)
Drug properties	In compositions of drugs of insecticidal,	Nontoxic to animal cells and bacteria.	Nontoxic to animal cells and bacteria.
	pesticidal, veterinary medicines and	During bioassays the oyster sperms and	During bioassays the oyster sperms and
	cosmetics for sunscreens.	bacteria remained alive in the sets treated	bacteria remained alive in the sets treated
	(see examples 19-23)	with different concentrations.	with different concentrations.
		The dye can be useful in drug delivery	The dye can be useful in drug delivery
		studies for in situ applications	studies for in situ applications
		(see examples 17, 18)	(see examples 13, 14)
Cell membrane	Stains and fluoresce live, dead, refrigerated	Stains and fluoresce live, and fixed cells. Do	Stains and fluoresce live, and fixed cells. Do
permeability	and fixed tissues.	not stain dead animal and bacterial cells.	not stain dead animal and bacterial cells.
	Dye is cell membrane permeant	Dye is cell membrane permeant	Dye is cell membrane permeant
	It is permeable to the nuclear membrane. It	It is permeable to the nuclear membrane. It	It is permeable to the nuclear membrane. It
	also stains chromatin.	also stains chromatin.	also stains chromatin.
	(see examples 21)	(see examples 24)	(see example 15)
Agglutination	Do not induce agglutination	Induces agglutination in oyster sperms, eggs	Neither induces agglutination in cells nor
induction		and bacterial cells but do not kill them.	kill them
		(see examples 14, 15)	(See Examples 9, 10)
Effect on rate of	No effect on cell lines	Enhances rate of fertilization	No effect
fertilization of		(see examples 16)
oyster gametes
Biosurfactant	Biosurfactant nature present	Biosurfactant nature absent	Biosurfactant nature absent
nature	(see example 9)
Live/Dead	Stains and fluoresce all kind of cells and	Stains and fluoresce only live and fixed	Stains and fluoresce only live and fixed
bacterial	cellulose	cells. The dead bacteria do not stain and do	cells. The dead bacteria do not stain
contaminations	(see examples 12-17)	not fluoresce.	and do not fluoresce.
checks		(see examples 22)	(see examples 14, 16, 18)
Live/Dead	Stains and fluoresce all kind of cells and	Stains and fluoresce only live and fixed	Stains and fluoresce only live and fixed
animal cell	cellulose	cells. The dead animal cells do not stain and	cells. The dead animal cells do not stain
sorting in tissue	(see examples 12-17)	do not fluoresce.	and do not fluoresce.
cultures		(see examples 24)	(see examples 13, 15, 17)
Non-radioactive	Dye is non-radioactive as it is not a	Dye is non-radioactive as it is not a	Dye is non-radioactive as it is not a
dye	synthetic dye but is natural dye. Useful for	synthetic dye but is natural dye.	synthetic dye but is natural dye.
	in situ non-radioactive kit compositions.	Dye is non-radioactive as it is not a	Dye is non-radioactive as it is not a
		synthetic dye but is natural dye.	synthetic dye but is natural dye.
Photobleaching/	i.	Do not photobleach while screening	Do not photobleach while screening	Do not photobleach while screening
		slides.
Photostability	ii.	Photostable at the room temperature	slides.	slides.
		over one year	Photostable at 4 degree centigrade but	Photostable at the room temperature for
	iii.	the fluorescence of the	after staining the cells, it remains non	several months.
		dye does not change even when frozen at	degradable even at the room	The stained slides do not destain and
		minus 20° C., a temperature at which	temperature for several months.	preserve fluorescence which enhances
		the molecules are unable to attain the	The stained slides do not destain and	with maturity of slides.
		energy necessary for activation like in	preserve fluorescence.	The fluorescence of the dye does not
		extracts from luminescent organisms.	The fluorescence of the dye does not	change even when frozen at minus
		(see example 18)	change even when frozen at minus	20° C., a temperature at which the
			20° C., a temperature at which the	molecules are unable to attain the
			molecules are unable to attain the	energy necessary for activation like in
			energy necessary for activation like in	extracts from luminescent organisms.
			extracts from luminescent organisms.	(see example 5)
			(see examples 4, 25)
Quantum of		Very bright even at dilutions of 1:40000	Very bright even at dilutions of 1:400000	Higher than both the earlier dyes
fluorescence		(see examples 14)	and above	being much more brighter even at
			(see examples 18, 19, 22)	dilutions of 1:400000-1:900000
				and above.
				(see examples 15, 16, 19)
Antimicrobial/		Antimicrobial/insecticidal/	Antimicrobial/insecticidal/	Antimicrobial/insecticidal/
insecticidal/		Pesticidal activities present.	Pesticidal activities absent.	Pesticidal activities absent.
Pesticidal		(see examples 10)	(see examples 17, 18)	(see examples 13, 14)
bioactivities
Emission ranges	1.	Dye emits three different colored	1.	dye emits six different colored	1.	dye emits six different colored
of dyes when		emissions		fluorescence at 3 different wavelengths		fluorescence at 3 different wavelengths
excited with	2.	Fluorescence blue color emission occur in		of the UV and visible ranges of the		of the UV and visible ranges of the
cubes of		the 380 nm-400 nm range of UVA when		fluorescent cubes of an epifluorence		fluorescent cubes of an epifluorescence
fluorescent		excited under ultra violet cube WU - 330		microscope,		microscope,
olympus BX-60		nm-385 nm excitation range,	2.	dye emits three different colored	2.	dye emits three different colored
microscope of	3.	Fluorescence yellow color emission		fluorescence at 3 different wavelengths		fluorescence at 3 different wavelengths
Olympus Co.		occurs in the 500 nm-570 nm range		of the UV and visible ranges of the		of the UV and visible ranges of the
Ltd Japan		when excited under WB cube of 450 nm-		fluorescent cubes of an epifluorescence		fluorescent cubes of an epifluorescence
having different		480 nm excitation range,		microscope when attached to the cell		microscope when attached to the cell
excitation	4.	fluorescence orange color emission		membranes. These three emission		membranes. These three emission
wavelength		occurs in the 570 nm-650 nm range		ranges are different from that of the dye		ranges are different from that of the dye
ranges:		when excited under WG cube of 510 nm-		alone.		alone.
WU range 330-		550 nm excitation range,	3.	Fluorescence blue color Emission occur	3.	fluorescence blue color emission occur
385 nm	5.	Phase contrast effect under bright field		in the 450 nm-470 nm range when dye		in the 450 nm-470 nm range when dye
WB range 450-		(see examples 14-17)		in solution is excited under ultra violet		in solution is excited under ultra violet
480				cube WU - 330 nm-385 nm excitation		cube WU - 330 nm-385 nm excitation
WG range 510-				range,		range,
550 nm			4.	fluorescence green color emission	4.	fluorescence green color emission
Bright field				occurs in the 510 nm-570 nm range		occurs in the 510 nm-570 nm range
				when dye in solution is excited under		when dye in solution is excited under
				WB cube of 450 nm-480 nm excitation		WB cube of 450 nm-480 nm excitation
				range,		range,
			5.	fluorescence orange color emission	5.	fluorescence orange color emission
				occurs in the 610 nm-650 nm range		occurs in the 610 nm-650 nm range
				when dye solution is excited under WG		when dye solution is excited under WG
				cube of 510 nm-550 nm excitation		cube of 510 nm-550 nm excitation
				range,		range,
			6.	the dye emits hues of yellowish grays	6.	the dye emits hues of yellowish grays
				under the ordinary transmitted light bulb		under the ordinary transmitted light bulb
				of the epifluorescence microscope when		of the epifluorescence microscope when
				seen under 100X objective,		seen under 100X objective,
			7.	fluorescence blue color emission occur	7.	fluorescence blue color emission occur
				in the 470 nm-500 nm range when dye		in the 470 nm-500 nm range when dye
				attached to the cell membranes is		attached to the cell membranes is
				excited under ultra violet cube WU -		excited under ultra violet cube WU -
				330 nm-385 nm excitation range,		330 nm-385 nm excitation range,
			8.	fluorescence green color emission	8.	fluorescence green color emission
				occurs in the 570 nm-610 nm range		occurs in the 570 nm-610 nm range
				when dye attached to the cell		when dye attached to the cell
				membranes is excited under WB cube of		membranes is excited under WB cubes of
				450 nm-480 nm excitation range,		450 nm-480 nm excitation range,
			9.	fluorescence orange color emission	9.	ix. Fluorescence orange color emission
				occurs in the 610 nm-650 nm range		occurs in the 610 nm-650 nm range
				when dye attached to the cell		when dye attached to the cell
				membranes is excited under WG cube		membranes is excited under WB cube
				of 510 nm-550 nm excitation range,		of 510 nm-550 nm excitation range,
			10.	the dye on cell membranes attached	10.	the dye on cell membranes attached
				emits hues of yellowish grays under the		emits hues of yellowish grays under the
				ordinary transmitted light bulb of the		ordinary transmitted light bulb of the
				epifluorescence microscope when seen		epifluorescence microsope when seen
				under 100X objective		under 100X objective
				(see examples 19-23)		(see examples 19-22)
Other chemical	1.	decolorization by a reducing agent,	1.	is a non-reducible dye	1.	No decolorization by a reducing agent,
and physical	2.	not a synthetic compound,	2.	not a synthetic compound,	2.	not a synthetic compound,
Characteristics	3.	crude extract of the dye is yellowish	3.	crude extract of the dye is yelowish	3.	crude extract of the dye is orange in
of the dye		green in color,		orange in color,		color,
	4.	purified dye being reddish brown colored	4.	partially purified dye being light	4.	The dye is in the solution form
		powder when seen with the naked eye in		yellowish orange in color when seen	5.	The dye is extracted from alcoholic
		the daylight,		with the naked eye in the daylight,		extract of the female gonads.
	5.	Under tube light some hues of green are	5.	under tube light hues of multicolors are	6.	The alcoholic extract is heated and dried
		emitted,		emitted,		at 80 degrees centigrade.
	6.	amorphous in nature,	6.	cannot be made into powder	7.	The dried mass is dissolved in solvent
	7.	soluble in water,	7.	is in a solution form		ether
	8.	insoluble in the organic solvents like	8.	soluble in 70% ethyl alcohol, dilutions	8.	The dissolved dye pigment extract is
		ethanol, methanol and acetone,		can be made in water/seawater.		filtered through whattman filer No. 1.
	9.	is negatively charged,	9.	is negatively charged,	9.	The partially purified dye is also orange
	10.	has a pH of 6.5,	10.	has a pH of 6.8-7.5,		in color.
	11.	Presence of a phenolic group	11.	absence of a reducible group	10.	under tube light it emits variety of
	12.	absence of a quinoid ring,	12.	proteinaceous in nature,		colors of the visible light spectrum at
	13.	absence of a aromatic amine group	13.	The solvent front of TLC is 12.1 cm,		different angles.
	14.	reducing sugar is absent,		four spots present.	11.	the colored pigment of the dye is
	15.	pigment cum dye is a fluorescent dye	14.	Compound 1 spot has distance migrated		insoluble in water and alcohol.
		and emits fluorescence when excited		of 11.1 cm. Its Rf value is 0.917.	12.	Tthe partially purified dye pigment is
		with different wavelengths of UV and	15.	Compound 2 spot has distance migrated		soluble in solvent ether.
		visible spectral ranges on a		of 9.9 cm. Its Rf value is 0.818.	13.	The further dilutions of the dye in
		spectrophotometer,	16.	Compound 3 spot has distance migrated		experiments with animal and bacterial
	16.	UV, visible spectroscopy from 300 nm-		of 8.0 cm. Its Rf value is 0.661.		cells in water and seawater can be made
		700 nm and the peaks are marked at 379	17.	Compound 4 spot has distance migrated		by dissolving the ether extract of the dye
		nm and 439 nm wavelengths,		of 5.6 cm. Its Rf value is 0.463		in different desired concentrations and
	17.	UV, visible spectroscopy from 250 nm-	18.	It has carbohydrate		creating tribulations artificially.
		350 nm and the peaks are at 272 nm	19.	It has protein	14.	The dye comes in contact with the cells
		and 299 nm wavelengths,	20.	At least one of the proteins is a		and immediately permeates through the
	18.	Fluorescent spectroscopy in the UV and		glycoprotein		membranes and stain them.
		visible spectra, when excited with UV	21.	UV, visible spectroscopy the wavelength	15.	the dye has a pH of 7.0.
		270 nm wavelength the fluorescence is		of excitation was maximum at 351 nm,	16.	there is absence of a reducible group.
		emitted in the 324 nm-380 nm range		580 nm, 720 nm.		(see example 1-22)
		which comes under the UVA wavelength	22.	the fluorescence emission spectrometric
		range of ultraviolet rays of the sunlight,		analysis was in between 400 to 600 nm
	19.	with excitation wavelength 450 nm in		when excited at 351 nm.
		Fluorescent spectroscopy the	23.	The emission maxima were two peaks at
		fluorescence emission occurred at		450 nm and 550 nm.
		500 nm-580 nm with maximum		(see examples 1-25)
		intensity,
	20.	with excitation wavelength 540 nm in
		Fluorescent spectroscopy, the
		500 nm-620 nm with maximum intensity,
	21.	with excitation wavelength 555 nm in
		Fluorescent spectroscopy, the
		fluorescence emission occurred at 575
		nm-620 nm with maximum intensity,
	22.	physical checking of Whatman Filter
		no. 1 dipped with dye concentration
		1:40000 dilution under UV
		transilluminator and Gel Documentation
		system with UV bulbs of 260 nm-280 nm
		range emit bluish green hue color of
		fluorescence.
		(see examples 1-23)
Advantages	1.	dye is natural and not synthetic so steps	1.	dye is natural and not synthetic so steps	1.	dye is natural and not synthetic so
over presently		of harsh treatments with acids and		of harsh treatments with acids and		steps of harsh treatments with acids
marketed dyes		alkalies which are harmful to the		alkalies which are harmful to the		and alkalies which are harmful to
and common to		environment are not required. (see		environment are not required. (see		the environment are not required.
all the three yes		examples 1, 2)		examples 1, 2)		(see examples 1, 2)
	2.	The dye fits in the criterion of a good	2.	The dye fits in the criterion of a good	2.	The dye fits in the criterion of a
		dye according to which differentiation		dye according to which differentiation		good dye according to which
		of various part of the cell can be done		of various part of the cell can be done		differentiation of various part of
		under the same excitation range. (see		under the same excitation range. (see		the cell can be done under the
		example 21)		example 24)		same excitation range. (see
						example 15)
	3.	The dye is nonradiactive as it is a dye	3.	The dye is nonradiactive as it is a dye	3.	The dye is nonradiactive as it is a dye
		from a natural source and not synthetic.		from a natural source and not synthetic.		from a natural source and synthetic.
		(see examples 1, 2)		(see example 1, 2)		(see examples 1, 2)
	4.	the dye has antibacterial quality (see	4.	the dye is useful in drug industry	4.	the dye is useful in drug industry for
		example 10)		making kits for checking bacterial		making kits for checking bacterial
	5.	it has insecticidal qualities (see		contaminations. (see example 17, 18)		contaminations. (see example 13, 14)
		example 19)	5.	the dye is useful in medical applications	5.	the dye is useful in medical applications
	6.	the dye has pesticidal qualities. it kills		where fluorescence based in situ follow		where fluorescence based in situ
		dog fleas and ticks (see example 23)		up of drugs or molecules need to be		follow up of drugs or molecules
	7.	the dye is useful in drug industry for		seen since the dye is cell membrane		need to be seen since the dye is
		making veterinary and insecticidal		permeant and nontoxic to cells. (see		cell membrane permeant and
		compositions.		example 24)		nontoxic to cells. (see example 15)
	8.	the dye is useful in medical applications	6.	This dye in its single form is equivalent	6.	This dye in its single form is equivalent
		where X-ray defraction based studies		to six different synthetic fluorochromes		to six different synthetic fluorochromes
		are needed. It can be a visual reality		giving same colored emission of		giving same colored emission of
		without even exposing them on the the		fluorescent colors. While earlier		fluorescent colors. While earlier
		X-ray films.		fluorochromes needs to be used in		fluorochromes needs to be used in mixed
	9.	This dye in its single form is equivalent		mixed combinations this dye is a single		combinations this dye is a single dye
		to three different synthetic		dye showing those effects. (see		showing those effects.	(see example 19-
		fluorochromes giving same colored		example 19-23)		22)
		emission of fluorescent colors. (see	7.	The dye can be used as a quick	7.	The dye can be used as a quick
		example 14-17)		microscopic stain giving a phase		microscopic stain giving a phase contrast
	10.	The dye can be used as a quick		contrast effect		effect without any extra expenses on
		microscopic stain giving a phase		without any extra expenses on phase		phase contrast accessory of a
		contrast effect without any extra		contrast accessory of a microscope and		microscope and without any lengthy
		expenses on phase contrast accessory of		without any lengthy protocols of		protocols of fixations and preservations
		a microscope and without any lengthy		fixations and preservations of		of specimens. Especially on the spot
		protocols of fixations and preservations		specimens.Especially on the spot quality		quality check of live samples. (see
		of specimens. Especially on the spot		check of live samples. (see example 19-		example 19-22)
		quality check of live samples. (see		23)	8.	Being non degradable in quality of
		example 21)	8.	Being non degradable in quality of		fluorescense for longer durations, it does
	11.	Being non-degradable in quality of		fluorescence for longer durations, it		not require refrigeration while
		fluorescence for longer durations, it		does not require refrigeration while		exporting. The presently marketed
		does not require refrigeration while		exporting. The presently marketed		fluorescent dyes exported under
		exporting. The presently marketed		fluorescent dyes exported under		refrigeration equivalent to −20 degree
		fluorescent dyes exported under		refrigeration equivalent to −20 degree		centigrade. (see example 6)
		refrigeration equivalent to −20 degree		centigrade. (see example 4, 25)	9.	Unlike the earlier known Green
		centigrade. (see example 18)	9.	Unlike the earlier known Green		Fluorescent protein (GFP) from a marine
	12.	Unlike the earlier known Green		Fluorescent protein (GFP) from a		jellyfish, the present dye is not a protein.
		Fluorescent protein ( GFP) from a		marine jelly fish, our dye is though		The results are direct and 6 colored
		marine jelly fish, our dye is not a protein		also is a protein but is not a reporter		emissions occurs at three excitation
		and a reporter gene. The results are		gene. The results are direct and 6		wavelengths. (see example 2, 4, 8, 13)
		direct. GFP absorbs blue light at 395 nm		colored emissions occurs at three	10.	the dye is soluble in solvent ether and is
		and with a minor peak at 470 nm emits		excitation wavelengths. (see example		insoluble in water and alcohol. This
		green light. Our dye emits 3 fluorescent		6, 8, 13)		gives its utility in specific dyes where
		colors and at three different fluorescent	10.	The dye is soluble in 70% alcohol (see		non-polar dyes are needed. (see example
		wavelengths. (see example 7)		example 2)		2)
	13.	The dye is soluble in water so can be	11.	The dye is negatively charged protein	11.	The dye non-polar and has no charge.
		used in components where water-		dye (see example 6, 8, 13)		(see example 2, 4, 8, 13)
		soluble dyes are needed. The dye is	12.	The dye has a pH of 6.8-7.5 which is	12.	The dye has a pH of 7.0 and hence will
		insoluble in the organic solvents like		almost neutral and hence will not effect		not effect final properties of pH in
		ethanol, methanol and acetone.		final properties of pH drastically in		compositions. (see example 6)
		(see example 2)		compositions. (see example 6)	13.	The dye is non-proteinaceous in nature
	14.	The dye is negatively charged (see	13.	The dye is proteinaceous in nature and		so non-degradable under natural
		example 8)		stable at 4 degree centigrade but once it		conditions. (see example 5)
	15.	The dye has a pH of 6.5 which is almost		stains the cell membranes the	14.	The dye emmitted these fluorescence colors
		neutral and hence will not effect final		fluorescence of cells is nondegradable		even at a dilution range of 1:450000
		Properties of pH drastically in		for several months. (see example 4, 25)		times to 1:900000 times and above The
		compositions. (see example 24)	14.	The dye emitted these fluorescence		fluorescence of the extract persisted even
	16.	The dye is non-proteinaceous in nature so		colors even at a dilution range of		after at least 1 year at the room
		non degradable under natural conditions.		1:400000 times and above The		temperature. These multicolored
		(see example 18)		fluorescence of the extract persisted		emissions of the dye at different
	17.	The dye has nature of a biosurfactant so		even after several months at the room		wavelengths of excitations are
		can be used in soaps and toiletry		temperature. These multicolored		Comparable to the fluorochrome
		compositions. (see example 9)		emissions of the dye at different		micorscopic stains already in the market.
	18.	The dye has antimicrobial qualities (see		wavelengths of excitations are		(see example 19-23)
		example 10)		comparable to the fluorochrome	15.	The blue colored fluorescence of the
	19.	The dye emitted these fluorescence colors		microscopic stains already in the		present dye is comparable to the
		even at a dilution range of 1:40000 times		market. (see example 18, 19, 22)		emission of same color by DAPI
		(i.e. 1 gm powder of dye dissolved in 40	15.	The blue colored fluorescence of the		fluorochrome at the same wavelength
		liters of ultrapure water). The		present dye is comparable to the		excitation, used as components of the
		fluorescence of the extract persisted even		emission of same color by DAPI		non-radioactive labeling kits of
		after at least 1 year at the room		fluorochrome at the same wavelength		biochemistry, cell biology,
		temperature. These multicolored		excitation, used as components of the		immunochemistry, and molecurlar
		emissions of the dye at different		non-radioactive labeling kits of		biology. (See example 19-22).
		wavelengths of excitations are		biochemistry, cell biology,		16.	The blue colored fluorescence of the
		comparable to the fluorochrome		immunochemistry, and molecular		present dye is also comparable to the
		microscopic stains already in the market		biology. (see example 19-23)		emission of color by Hoechest 33258
		(see example 14).	16.	The blue colored fluorescence of the		used as components of the non-
	20.	The blue colored fluorescence of the		present dye is also comparable to the		radioactive labeling and detection kits of
		present dye is comparable to the emission		emission of color by Hoechest 33258		biochemistry, cell biology,
		of same color by DAPI fluorochrome at		used as components of the non-		immunochemistry, and molecular
		the same wavelength excitation, used as		radioactive labeling and detection kits		biology. (see example 19-22).
		components of the non-radioactive		of biochemistry, cell biology,	17.	The blue colored fluorescence of the
		labeling kits of biochemistry, cell		immunochemistry, and molecular		present dye is also comparable to the
		biology, Immunochemistry, and		biology. (see example 19-23)		emission of color by Hoechest 33342
		molecular biology. (see example 14-17)	17.	The blue colored fluorescence of the		fluorochrome at the same wavelength
	21.	The blue colored fluorescence of the		present dye is also comparable to the		excitation used as the same wavelength
		present dye is also comparable to the		emission of color by Hoechest 33342		non-radioactive labeling and detection
		emission of color by Hoechest 33258		fluorochrome at the same wavelength		kits of biochemistry, cell biology,
		used as components of the non-		excitation used as components of the		immunochemistry, and molecular
		radioactive labeling and detection kits of		non-radioactive labeling and detection		biology, (see example 19-22).
		biochemistry, cell biology,		kits of biochemistry, cell biology,	18.	The yellow colored fluorescence of the
		immunochemistry, and molecular		immunochemistry, and molecular		said dye in the visible range is
		biology. (see example 14-17)		biology. (see example 19-23)		comparable to the same colored
	22.	The blue colored fluorescence of the	18.	The yellow colored fluorescence of the		emissions of Acridine orange used as
		present dye is also comparable to the		said dye in the visible range is		components of the non-radioactive
		emission of color by Hoechest 33342		comparable to the same colored		labeling and detection kits of
		fluorochrome at the same wavelength		emissions of Acridine orange used as		biochemistry, cell biology,
		excitation used as components of the		components of the non-radioactive		immunochemistry, and molecular
		non-radioactive labeling and detection		labeling and detection kits of		biology, (see example 19-22).
		kits of biochemistry, cell biology,		biochemistry, cell biology,	19.	The yellow colored fluorescence of the
		immunochemistry, and molecular		immunochemistry, and molecular		said dye in the visible range is
		biology.(see example 14-17)		biology. (see example 19-23		comparable to the same colored
	23.	The yellow colored fluorescence of the	19.	The yellow colored fluorescence of the		emissions of auramine used as
		said dye in the visible range is		said dye in the visible range is		components of the non-radioactive
		comparable to the same colored		comparable to the same colored		labeling and detection kits of
		emissions of Acridine orange used as		emissions of auramine used as		biochemistry, cell biology,
		components of the		components of the non-radioactive		immunochemistry, and molecular
		Non-radioactive labeling and detection		labeling and detection kits of		biology. (see example 19-22).
		kits of biochemistry, cell biology,		biochemistry, cell biology,	20.	The yellow colored fluorescence of
		Immunochemistry, and molecular		immunochemistry, and molecular		the said dye in the visible range is
		biology.. (see example 14-17)		biology. (see example 19-23)		comparable to the same colored
	24.	The yellow colored fluorescence of the	20.	The yellow colored fluorescence of the		emissions of FITC used as components
		said dye in the visible range is		said dye in the visible range is		of the non-radioactive labeling and
		comparable to the same colored		comparable to the same colored		detection kits of biochemistry, cell
		emissions of auramine used as		emissions of FITC used as components		biology., immunochemistry, and
		components of the non-radioactive		of the non-radioactive labeling and		molecular biology. (see example 19-22).
		labeling and detection kits of		detection kits of biochemistry, cell	21.	The orange colored fluorescent emission
		biochemistry, cell biology,		biology, immunochemistry, and		is comparable to the orange
		immunochemistry, and molecular		molecular biology. (see example 19-23)		fluorescence Color of Propidium Iodide
		biology.. (see example 14-17)	21.	The orange colored fluorescent emission		fluorochrome used as components of the
	25.	The yellow colored fluorescence of the		is comparable to the orange fluorescence		non-radioactive labeling and detection
		said dye in the visible range is		color of Propidium Iodide fluorochrome		kits of biochemistry, cell biology,
		comparable		used as components of the non-		immunochemistry, and molecular
		To the same colored emissions of FITC		radioactive labeling and detection kits		biology. (see example 19-22).
		used as components of the non-		of biochemistry, cell biology	22.	The orange colored fluorescent emission
		radioactive		immunochemistry, and molecular		is comparable to the orange
		Labeling and detection kits of		biology. (see example 19-23)		fluorescence Color of Rhodamine
		biochemistry, cell biology,	22.	The orange colored fluorescent emission		non-radioactive Labeling and detection
		immunochemistry, and		is comparable to the orange		kits of biochemistry, cell biology,
		Molecular biology.. (see examples 14-		fluorescence color of Rhodamine		immunochemistry, and molecular
		17)		fluorochrome used as components of the		biology. (see example 19-22).
	26.	The orange colored fluorescent emission		non-radioactive labeling and detection	23.	The orange colored fluorescent emission
		is comparable to the orange fluorescence		kits of biochemistry, cell biology,		is comparable to the ornage
		color of Propidium Iodide fluorochrome		immunochemistry, and molecular		fluorescence color of TRITC
		used as components of the non-		biology. (see example 19-23)		fluorochrome used as components of the
		radioactive	23.	The orange colored fluorescent emission		non-radioactive labeling and detection
		labeling and detection kits of		is comparable to the orange fluorescence		kits of biochemistry, cell boilogy,
		biochemistry, cell biology,		color of TRITC fluorochrome used as		immunochemistry, and molecular
		immunochemistry, and		components of the non-radioactive		biology.. (see example 19-22).
		molecular biology.. (see example 14-		labeling and detection kits of	24.	Unlike the synthetic commercial dyes
		17)		biochemistry, cell biology,		used for the same purposes, the present
	27.	The orange colored fluorescent emission		immunochemistry, and molecular		dye is stable at the room temperature
		is comparable to the orange fluorescence		biology. (see example 19-23)		and has a long shelf life. Molecular non-
		color of Rhodamine fluorochrome used as	24.	Unlike the synthetic commercial dyes		radioactive kits of the said dye can
		components of the non-radioactive		used for the same purposes, the present		be exported at the room temperatures..
		labeling and detection kits of		dye is stable at the room temperature		(see example 19-22).
		biochemistry, cell biology,		and has a long shelf life. Molecular non-	25.	The said single dye has characteristics
		immunochemistry, and		radioactive kits of the said dye can be		of at least one hundred and twenty three
		molecular biology.. (see example 14-		exported at the room temperatures. (see		different fluorochromes (DAPI,
		17)		example 19-23)		Hoechest 33258, Hoechest 33342,
	28.	The orange colored fluorescent emission	25.	The said single dye has characteristics		FITC, acridine orange,
		is comparable to the orange fluorescence		of at least one hundred and twenty three		auramine, Rhodamine, TRITC, and
		color of TRITC fluorochrome used as		different fluorochromes (DAPI,		propidium iodide etc.) now in the
		components of the non-radioactive		Hoechest 33258, Hoechest 33342,		market. (see example 19-22).
		labeling		FITC, acridine orange,	26.	Under ordinary light of microscope
		and detection kits of biochemistry, cell		auramine, Rhodamine, TRITC, and		the hues of grays produce a phase
		biology, immunochemistry, and		propidium iodide etc.) now in the		contrast effect which is useful in
		molecular		market. (see example 19-23)		rapid screening of cytogentical,
		biology.. (see example 14-17)	26.	under ordinary light of microscope		cytological, and histochemical slides
	29.	Unlike the synthetic commercial dyes		hues of grays produce a phase contrast		and save expenses on the extra
		used for the same purposes, the present		effect which is useful in rapid screening		phase contrast accessory
						component of microscope. The
		dye is stable at the room temperature and		of cytogentical, cytological, and		fluorescence color emissions follow
		has a long shelf life. Molecular non-		histochemical slides and save expenses		Stoke's law of fluorescence.. (see
		radioactive kits of the said dye can be		on the extra phase contrast accessory		example 19-22).
		exported at the room temperatures.. (see		component of microscope. The	27.	The microphotograhs with Kodak film
		example 18).		fluorescence color emissions follow		rolls show hues of the adjacent color
	30.	The said single dye has characteristics of		Stoke's law of fluorescence. (see		emission wavelengths. Like when seen
		at least one hundred and twenty three		example 19-23)		blue color fluorescence under the
		different fluorochromes (DAPI, Hoechest	27.	The microphotographs with Kodak film		epifluorescence microscope in
		33258, Hoechest 33342, FITC, acridine		rolls shows hues of the adjacent color		microphotograph the hues of green also
		orange, auramine, Rhodamine, TRITC,		emission wavelengths. Like when seen		comes.. (see example 19-22).
		and propidium iodide etc.) now in the		blue color fluorescence under the	28.	The microphotographs with Kodak film
		market.		epifluorescence microscope in		rolls shows hues of the adjacent color
	31.	under ordinary light of microscope the		microphotograph the hues of green also		Emission wavelengths. Like when seen
		hues of grays produce a phase contrast		comes. (see example 19-23)		yellow color fluoroscence under the
		effect which is useful in rapid screening	28.	The microphotographs with Kodak film		epifluorescence microscope in
		of cytogentical, cytological, and		rolls shows hues of the adjacent color		microphotograph the hues of green also
		histochemical slides and save expenses		emission wavelengths. Like when seen		comes. The dye when seen orange
		on the extra phase contrast accessory		yellow color fluorescence under the		fluorescence color under the
		component of microscope. The		epifluorescence microscope in		epifluorescence microscope in
		fluorescence color emissions follow		microphotograph the hues of red also		Microphotograph the hues of red also
		Stoke's law of fluorescence.		comes. The dye when seen orange		comes.. (see example 19-22).
	32.	The microphotographs with Kodak film		fluorescence color under the	29.	The cytogenetic slides seen under all
		rolls shows hues of the adjacent color		epifluorescence microscope in		fluorescence gives a counterstain effect
		emission wavelengths. Like when seen		microphotograph the hues of red also		of cells with the background where no
		blue color fluorescence under the		comes. (see example 19-23)		specimen but only dye is present.. (see
		epifluorescence microscope in	29.	The cytogenetic slides seen under all		example 19-22).
		microphotograph the hues of green also		fluorescence gives a counterstain effect	30.	The dye can be used for the preparation
		comes.		of cells with the background where no		of polyvinyl chloride film that exhibits
	33.	The microphotographs with Kodak film		specimen but only dye is present. (see		fluorescent colors. It also can be used in
		rolls shows hues of the adjacent color		example 19-23)		fluorescent colors in variety of paints,
		emission wavelengths. Like when seen	30.	The dye can be used for the preparation		inks and textiles.
		yellow color fluorescence under the		of polyvinyl chloride film that exhibits	31.	The dye can be used in compositions of
		epifluorescence microscope in		fluorescent colors. It also can be used in		fluorescent dye for bleaching and
		microphotograph the hues of green also		fluorescent colors in variety of paints,		brightening polymer. The dye can be
		comes. The dye when seen orange		inks, textiles.		used in leak detection with a full
		fluorescence color under the	31.	The dye can be used in compositions of		spectrum fluorescent dye. It can also be
		epifluorescence microscope in		fluorescent dye for bleaching and		used in automated chemical metering
		microphotograph the hues of red also		brightening polymer. The dye can be		system. It can also be used to mark the
		comes.		used in leak detection with a full		location of crashed aircrafts, life crafts,
	34.	The cytogenetic slides seen under all		spectrum fluorescent dye. It can also be		and equipment for example rockets.
		fluorescence gives a counterstain effect of		used in automated chemical metering		Furthur it can be used in under sea
		cells with the background where no		system. It can also be used to mark the		probes. The dye can be used in photo
		specimen but only dye is present.		location of crashed aircrafts, life crafts,		chemotherapy of skin cancers.
	35.	The dye can be used for the preparation		and equipment for example rockets.	32.	It can be used as fluorescent in situ
		of polyvinyl chloride film that exhibits		Further it can be used in under sea		hybridization application kit component
		fluorescent colors. It also can be used in		probes. The dye can be used in photo		for =molecular diagnostics. It can also be
		fluorescent colors in variety of paints,		chemotherapy of skin cancers.		used as a component of the non-
		inks, textiles.	32.	It can be used as fluorescent in situ		radioactive labeling and detection kits of
	36.	The dye can be used in compositions of		hybridization application kit component		biochemistry, cell biology,
		fluorescent dye for bleaching and		for molecular diagnostics. It can also be		immunochemistry, and molecular
		brightening polymer. The dye can be used		used as a component of the non-		biology for labeling of DNA, RNA,
		in leak detection with a full spectrum		radioactive labeling and detection kits of		Proteins and enymes.,
		fluorescent dye. It can also be used in		biochemistry, cell biology,		Immunofluorescent detections,
		automated chemical metering system. It		immunochemistry, and molecular		Counterstain of DIG-labeled
		can also be used to mark the location of		biology for labeling of DNA, RNA,		oliogonucleotide probes and Anti-DIG
		crashed aircrafts, life crafts, and		Proteins and enzymes,		Fab-fragments, Single and multiple cell
		equipment for example rockets. Further it		Immunofluorescent detections,		quantitative fluorescence in
		can be used in under sea probes. The dye		Counterstain of DIG-labeled		Flowcytometry., Fluorochrome stains for
		can be used in photo chemotherapy of		oliogonucleotide probes and Anti-DIG		epifluorescence microscopy
		skin cancers.		Fab-fragments, Single and multiple cell	33.	The dye can be used for a quick check of
	37.	The dye can be used as chromatophore		quantitative fluorescence in		biocontamination in the health food
		sunscreen component of cosmetics		Flowcytometry., Fluorochrome stains		industry, cosmetic industry,
		creams and lotions.		for epifluorescence microscopy.		pharmaceutical and chemical industries,
	38.	The water miscible quality of the dye can	33.	The dye can be used for a quick check of		for rapid estimations of biocontaminants
		make it easily miscible in moisturizers. It		biocontamination in the health		in laboratory cultures, for a rapid check
		can be used as fluorescent in situ		food industry, cosmetic industry,		of biopollutants under field conditions
		hybridization application kit component		pharmaceutical and chemical industries,	34.	The dye can be used natural colorant
		for molecular diagnostics. It can also be		for rapid estimations of		35.	The dye being a non-polar fluorochrome,
		used as a component of the non-		biocontaminants in laboratory cultures,		which is separated from the protein part,
		radioactive labeling and detection kits of		for a rapid check of biopollutants under		can be used in formulations of variety of
		biochemistry, cell biology,		field conditions (see example 24)		new molecules by attachments.. (see
		immunochemistry, and molecular	34.	The dye can be used natural colorant		example 2, 4, 8, 13)
		biology for labeling of DNA, RNA,	35.	Dye can be used in fertilization rate
		Proteins and enzymes,		enhancements in medical, biomedical,
		Immunofluorescent detections,		agricultural and aquaculture science (see
		Counterstain of DIG-labeled		example 14, 15)
		oliogonucleotide
		probes and Anti-DIG Fab-fragments,
		Single and multiple cell quantitative
		fluorescence in Flowcytometry.,
		Fluorochrome stains for epifluorescence
		microscopy.
	39.	The dye can be used for a quick check of
		biocontamination in the health food
		industry, cosmetic industry,
		for rapid estimations of biocontaminants
		in laboratory cultures, for a rapid check
		of biopollutants under field conditions. It
		can also be a competitive inhibitor of
		cholinesterases.
	40.	The dye can be used in anti microbial
		compositions.
	41.	The dye can be used as a biosurfactant in
		toiletry compositions
	42.	The dye can be used natural colorant
Specific uses of	a.	preparation of flexible polyvinyl	a.	use of fluorescent colors in variety of	a.	use of fluorescent colors in variety
the 3 natural		chloride film that exhibits		paints, inks, textiles;		of paints, inks, textiles;
fluorescent dyes		fluorescent colors;
described here.	b.	.use of fluorescent colors in variety of	b.	a composition of fluorescent dye for	b.	a composition of fluorescent dye for
	paints, inks, textiles;		bleaching and brightening polymer;		bleaching and brightening polymer;
	c.	a composition of fluorescent dye for	c.	leak detection with a full spectrum	c.	leak detection with a full spectrum
		bleaching and brightening polymer;		fluorescent dye;		fluorescent dye;
	d.	leak detection with a full spectrum	d.	use in automated chemical metering	d.	use in automated chemical metering
		fluorescent dye;		system;		system;
	e.	use in automated chemical metering	e.	to mark location of crashed air-crafts,	e.	to mark location of crashed
		system;		life crafts, and equipment for example		air-crafts, life crafts, and
	f.	.to mark location of crashed air-crafts,		rockets;		equipment for example rockets;
		life crafts, and equipment for example	f.	under sea probes;	f.	under sea probes;
		rockets;	g.	fluorescent in situ hybridization	g.	chromatophore sunscreen component of
	g.	under sea probes;		application kit component for molecular		cosmetics creams and lotions;
	h.	UVA is used in photo chemotherapy of		diagnostics;	h.	fluorescent in situ hybridization
		skin cancers;. (see example 11)	h.	component of the non-radioactive		application kit component for molecular
	i.	Chromatophore sunscreen component of		labeling and detection kits of		diagnostics;
		cosmetics creams and lotions;		biochemistry, cell molecular	i.	component of the non-radioactive
	j.	the water miscible quality of the dye can		immunochemistry, and molecular		labeling and detection kits of
		make it easily miscible in moisturizers;		biology for labeling of DNA, RNA,		biochemistry, cell biology,
	k.	fluorescent in situ hybridization		Proteins and enzymes;		immunochemistry, and molecular
		application kit component for molecular	i.	immunofluorescent detections;		biology for labeling of DNA, RNA,
		diagnostics;	j.	counterstain of DIG-labeled		Proteins and enzymes;
	l.	component of the non-radioactive		oligonucleotide probes and Anti-DIG	j.	immunofluorescent detections;
		labeling and detection kits of		Fab-fragments;
		biochemistry, cell biology,	k.	single and multiple flow cytometry	k.	counterstain of DIG-labeled
		immunochemistry, and molecular		applications;		oligonucleotide probes and Anti-DIG
		biology for labeling of DNA, RNA,	l.	fluorochrome stains for epifluorescence		Fab-fragments;
		Proteins and enzymes;		microscopy;. (see example 19-23).	l.	singel and multiple flow cytometry
	m.	immunofluorescent detections;	m.	for a quick check of biocontamination		applications;
	n.	counterstain of DIG-labeled		in the health food industry, cosmetic	m.	fluorochrome stains for epifluorescence
		oligonucleotide probes and Anti-DIG		industry, pharmaceutical and chemical		microscopy;. (see example 19-22).
		Fab-fragments;		industries;. (see example 22).	n.	for a quick check of biocontamination in
	o.	single and multiple flow cytometry	n.	for rapid estimations of biocontaminants		the health food industry, cosmetic
		applications;		in laboratory cultures;. (see example		industry, pharmaceutical and chemical
	p.	fluorochrome stains for epifluorescence		22)		industries;. (see example 14, 16, 18)
		microscopy;	o.	for a rapid check of biopollutants under	o.	For rapid estimations of biocontaminants
	q.	for a quick of biocontamination in		field conditions;. (see example 22).		in laboratory cultures. (see example
		the health food industry, cosmetic	p.	agglutination compositions;. (see		14, 16 and 18)
		industry, pharmaceutical and chemical		example 14, 15)	p.	for a rapid check of biopollutants under
		industries;	q.	a natural colorant;		field conditions; (see example 14, 16, 18)
	r.	for rapid estimations of biocontaminants	r.	a bioactive composition of the marine	q.	for a rapid check of dead and live
		in laboratory cultures;		dye in the ratio of 1:400000 in ultrapure		bacteria E. coli .. (see example
	s.	for a rapid check of biopollutants under		water to obtain fluorescences of six		14, 16, 18)
		field conditions;		colors at six different wavelengths and a	r.	a natural colorant; a bioactive
	t.	a competitive inhibitor of		phase contrast effect under transmitted		composition of the marine dye in the
		cholinesterases;		light;. (see example 18, 19, 22)		ratio of 1:400000 to obtain
	u.	in antimicrobial compositions;. (see	s.	a dye for various fluorescent		fluorescences of six colors at three
		example 10)		applications to be performed in areas of		different wavelengths and a
	v.	as a biosurfactant in toiletry		sub zero temperatures.		phase contrast effect under transmitted
		compositions;. (see example 9)	t.	for fertilization rate increase in		light;. (see example 13, 14)
	w.	a natural colorant;		aquaculture industry. (see example	s.	a dye for various fluroescent applications
	x.	a bioactive composition of the marine		14, 15)		to be performed in areas of sub zero
		dye in the ratio of 1:40000 in ultrapure	u.	for cell permeant membrane dye		temperature.. (see example 5)
		water to obtain fluorescences of three		compositions.. (see example 24)	t.	a dye for making conjugants with variety
		colors at three different wavelengths and	v.	for identification of dead and live cells		of biomolecules.
		a phase		in tissue cultures.. (see example 24)	u.	for cell permeant membrane dye
		contrast effect under transmitted light;	w.	for identification of dead and live cells/		compositions.
		(see example 14)		bacteria in food industries. (see	v.	for identification of dead and live cells in
	y.	a dye br various fluorescent		example 24)		tissue cultures.. (see example 13, 15, 17)
		applications to be performed in areas of	x.	for dye compositions in biosensors	w.	for dye compositions in biosensors
		sub zero temperatures.. (see example	y.	as dye composition in molecular and	x.	as dye composition in molecular and
		18)		microbiological kits.. (see example		microbiological kits. (see example
				24)		13, 15, 17)
					y.	A non-polar dye for detection of lipids
						and oils.. (see example 4, 8, 11)

Claims

1. A non-polar and non-proteinaceous fluorescent dye obtained from an alcoholic extract of ovarian cells from the non bioluminescent marine organism Holothuria scabra, said dye having the following characteristics:i. having no decolorization when exposed to a reducing agent, ii. being a naturally produced compound, iii. orange in color in crude extract form, iv. bright orange in color in semi-purified form, v. emitting a variety of colors of the visible light spectrum, vi. having a pigment that is insoluble in water and alcohol, vii. having a pigment that is soluble in ether, viii. having pH 7.0, ix. not having a chromophore that can be reduced, x. emitting six different colored fluorescence at three different wavelengths of the UV and visible ranges, xi. emitting fluorescence of blue color emission in the 450 nm-470 nm range on excitation under light in the 330 nm-385 nm range, xii. emitting fluorescence of yellowish green color emission in the 510 nm-570 nm range on excitation under light in the 450 nm-480 nm range, xiii. emitting fluorescence of orange color emission in the 610 nm-650 nm range on excitation under light in the 510 nm-550 nm excitation range, xiv. emitting yellowish gray emission under light in the spectrum visible to the human eye, xv. emitting detectable fluorescence at a dilution range of 1:900,000 times xvi. the fluorescence of the dye persists even up to one year when preserved at about 4° C., xvii. the fluorescence of the dye is highly stable against long expospres to direct light, xviii. the fluorescence of the dye does not change when the dye is frozen, xix. the dye is nontoxic, xx. the dye is permeable to living cell membranes, xxi. the dye is impermeable to dead eukaryotic cells and dead prokaryotic cells, and xxii. the dye is not degraded after staining cell components.

2. The dye according to claim 1 having multicolored emissions at different wavelengths of excitations.

3. The dye according to claim 1 having a blue colored fluorescence depending upon excitation wavelength.

4. The dye according to claim 1 having a yellow colored fluorescence depending upon excitation wavelength.

5. The dye according to claim 1 having an orange colored fluorescence depending upon excitation wavelength.

6. The dye according to claim 1 wherein the dye is stable at room temperature and has a long shelf life.

7. The dye according to claim 1 wherein the dye is incorporated into a kit which is exported at room temperature.

8. The dye according to claim 1 wherein the said dye is incorporated with a substrate for use in microscopy.

9. The dye according to claim 1 wherein the said dye is incorporated into a bioassay.

10. The dye according to claim 1 wherein the dye is incorporated with a cytogenetic slide.

11. The dye according to claim 1 wherein the dye is diluted with water in the ratio ranging between 1:450,000 to 1:900,000 giving fluorescence of six colors at three different wavelengths.

12. A composition comprising the dye according to claim 1 wherein the composition is used for at least one of the following applications:i. as a flourescent coating composition or ink; ii. as a fluorescent molecular probe; iii. within a kit used in experiments to be performed in locations at subzero ° C.; iv. as an agent for producing fluorochrome stains for epifluorescence microscopy; v. within cell permeant dye compositions; vi. a composition comprising the fluorescent dye for bleaching or brightening polymer; vii. within a kit for leak detection with a full spectrum fluorescent dye; viii. within an automated chemical metering system; ix. within a kit to mark a location; x. within an under sea probe; xi. as a sun screen component of cosmetic creams or lotions; xii. as a fluorescent in situ hybridization application kit component for molecular diagnostics; xiii. as a component of non-radioactive labeling and detection kits; xiv. as an immunofluorescent detection; xv. as a counterstain of oligonucleotide probes or Fab-fragments; xvi. as a component in single or multiple flow cytometry applications; xvii. as a fluorochrome stain for epifluorescence microscopy; xviii. as a component in a kit for detecting biocontamination in an industrial environment; xix. as a component in a kit for detecting biocontamination in a laboratory environment; xx. as a component in a kit for detecting biopollutants under field conditions; xxi. as a component in a kit for detecting dead and live bacteria; xxii. as a natural colorant; xxiii. as a bioactive composition; xxiv. as a dye for a fluorescent applications to be performed in areas of sub 0° C. temperatures; xxv. as a dye for making a conjugant with a biomolecule; xxvi. as a cell membrane permeant agent; xxvii. as a component for identification of dead and live cells in tissue cultures; xxviii. as a component for a biosensor; xxix. as a component in molecular and microbiological kits; and xxx. as a non-polar agent for detection of lipids and oils.

13. A process comprising diluting the dye according to claim 1 with water in the ratio ranging between 1:400,000 to 1:900,000 giving fluorescence of six colors at three different excitation wavelengths.

14. A process for preparation of a fluorescent dye from Holothuria scabra, which comprises the steps of:removing the female gonads from Holothuria scabra, extracting the gonads with alcohol to obtain a colored solution, filtering the colored solution to obtain partially purified extract, dissolving the extract in solvent ether, and filtering the dissolved extract to obtain the fluorescent dye.

15. A non-polar and non-proteinaceous fluorescent dye obtained from an alcoholic extract of ovarian cells from the non bioluminescent marine organism Holothuria scabra.