Lipase-mediated hydrolysis of corn DDGS oil: Kinetics of linoleic acid production

In this study, we investigated the kinetics of linoleic acid production via lipase-mediated hydrolysis of corn DDGS oil in a batch reactor with continuous mechanical agitation and developed a kinetic model that incorporated the product inhibition to study the complete hydrolysis. The model agreed very well with observed data; though situations with low enzyme dosage or low stirring rates were modeled successfully without product inhibition, actual product concentration in such situations was too low to exert any inhibitory effects. Increasing the enzyme concentration increased hydrolysis, and beyond certain enzyme concentrations, effects tended to fade away because of excessive enzyme desorption from the interface. An enzyme dosage within the range of 40–60 KLU/L of oil dispersion could be successfully applied for a substrate concentration of 25–50 g/L of DDGS oil. Increasing the agitation rates improved enzymatic hydrolysis, but a higher stirring rate of 1000 rpm moderately improved production of linoleic acid compared with a stirring rate of 750 rpm. Within the range of substrate concentrations studied, enzymatic inhibition was moderate but still evident. The high degree of hydrolysis (i.e., ∼96% of theoretical linoleic acid yield) from DDGS oil suggests this method has potential for commercial production of linoleic acid.     

Mechanical agitation of hybridoma suspension cultures: Metabolic effects of serum, pluronic F68, and albumin supplements

Metabolic effects of the medium supplements, fetal bovine serum (FBS), Pluronic F68, and bovine serum albumin (BSA) were compared for agitated bioreactor cultures of hybridoma cells. Agitation speeds up to 600 rpm, without entrainment of gas bubbles by sparging or vortex formation, allowed examination of cell interactions with turbulent fluid forces. For cultures in FBS-supplemented RPMI media, there was no significant effect of intense turbulent fluid shear on cell growth, metabolism, or antibody, production. Serum-free cultures (Pluronic F68 or BSA supplements) at 600 rpm demonstrated greatly increased glycolysis rates during exponential growth relative to controls. Nutrient limitations caused increased rates of decline of the viable cell concentrations and a reduction in final antibody titers by around 70%. The Pluronic F68 and BSA supplements did not lead to cell protection by modifying metabolism under conditions of intense turbulent fluid shear. Supplementing the protein-free medium with FBS reduced glycolysis rates in exponential growth phase, but this did not prevent a high rate of viable cell decline and low antibody titers. We concluded that FBS does not have a metabolic effect on cells subjected to intense turbulent fluid shear. Although the agitation conditions employed in this study were more intense than generally required for agitated bioreactor culture of hybridomas, we have demonstrated the importance of considering metabolic effects of turbulent fluid forces on cultures using nutrient-rich basal media, in addition to the considerations of gas bubble effects described by other workers. (c) 1992 John Wiley & Sons, Inc.     

Batch and fed-batch cultures of E. coli TB1 at different oxygen transfer rates

Batch cultures of E. coli TB1/pUC13 were carried out at different oxygen transfer rates (OTR) enhanced by the increase of stirring rate and by the increase of air total pressure of the bioreactor. These two variables showed to have little effect on cell growth but a negative effect on cytochrome b5 (recombinant protein) production. However, this effect was more significant of high stirring rates than for values of pressure up to 0.4?MPa. The effects of stirring and pressure were also investigated for fed-batch mode operation. In this type of cell cultivation high cell densities are reached, thus a high capacity of oxygen supply of the system is required. To compare the two ways of improving OTR, cell behaviour was followed in two bioreactors at different operational conditions giving the same maximum OTR value. The first one operated at a high stirring rate (500?rpm) and at atmospheric pressure (0.1?MPa) and the other one at high air pressure (0.48?MPa) and low stirring rate. The increased pressure seemed to be a better way of ensuring an adequate oxygen supply to a culture of E. coli TB1 cells than an increased stirring rate. For the high pressure experiment a higher cellular density was reached, as well as a higher cyt.b5 expression which led to a 4-fold increase in final productivity. These experiments showed that bioreactor pressurization can be successfully used as a means of enhancing oxygen mass transfer to shear sensitive cell cultures.     

Rheology and Shear Stress of Centaurea calcitrapa Cell Suspension Cultures Grown in Bioreactor

Centaurea calcitrapa suspension cultures were grown either in Erlenmeyer flasks or in a mechanically stirred bioreactor. Its rheological behaviour, when fitted to the Oswald–de Waele model (power law), showed pseudoplastic characteristics in both cases. The flow behaviour index (n) decreased over the course of a growth cycle and the consistency index (K) increased, reached a value of 1.81 N sⁿ m⁻² run on 2 l bioreactor. Bioreactor cultivation of C. calcitrapa cells at different agitation rates (30, 60, 100 and 250 rpm), highlighted the influence of shear forces on cell viability loss (90–34%) and phenol accumulation (74–140 μg l⁻¹), due to increased stirring speeds. Analysis of these results suggests that this cell line is shear-sensitive. An empirical exponential correlation was defined between apparent viscosity and biomass concentration, under the studied conditions, giving the possibility to estimate the prevailing broth regime and to optimize bioreactor design. Revisions requested 10 October 2005; Revisions received 19 December 2005     

Biodesulphurization of mengen lignite by Rhodoccocus rhodochrous in a batch stirred and aerated tank fermenter

The biodesulphurization of Mengen lignite by a mesophilic bacterium, Rhodococcus rhodochrus ATCC 53968, was investigated in a batch stirred and aerated reactor. The experiments were carried out at 28°C with an inoculum percentage, initial pH, initial sodium acetate and lignite concentration of the biodesulphurization medium of 8% [v/v], 6.5 mM, 20 mM and 20 g/l, respectively. Variations in the sulphur contents of the lignite relative to the biodesulphurization period were monitored. The effects of the stirring and aeration rates on the removal of different sulphur forms from coal were investigated in the ranges 450–1,200 rpm and 0.1–0.53 vvm and the optimum values were found to be 500 rpm and 0.18 vvm, respectively. An increase in the total sulphur reduction with increasing biodesulphurization time was observed. The maximum total sulphur removal percentage was found to be 15.2% at 1,200 rpm after four days of incubation. The highest total sulphur removal rate was calculated on the second day of microbial desulphurization for each run. The total and organic sulphur contents of the coal after biodesulphurization were correlated with the stirring and aeration rates by using the non-linear least squares regression method. In the experimental runs lasting 8 days, the highest organic sulphur reducing percentage of 10.1% was obtained at a stirring rate of 500 rpm and an aeration rate of 0.40 vvm.     

Implications of modifying membrane fatty acid composition on membrane oxidation,integrity, and storage viability of freeze‐dried probiotic,Lactobacillus acidophilus La‐5

The aim of this study was to investigate the effect of altering the fatty acid profile of the lipid membrane on storage survival of freeze‐dried probiotic, Lactobacillus acidophilus La‐5, as well as study the membrane integrity and lipid oxidation. The fatty acid composition of the lipid membrane of L. acidophilus La‐5 was significantly different upon growth in MRS (containing Tween 80, an oleic acid source), or in MRS with Tween 20 (containing C12:0 and C14:0), linoleic, or linolenic acid supplemented. Bacteria grown in MRS showed the highest storage survival rates. No indications of loss of membrane integrity could be found, and membrane integrity could therefore not be connected with loss of viability. Survival of bacteria grown with linoleic or linolenic acid was more negatively affected by the presence of oxygen, than bacteria grown in MRS or with Tween 20 supplemented. A small, but significant, loss of linolenic acid during storage could be identified, and an increase of volatile secondary oxidation products during storage was found for bacteria grown in MRS, or with linoleic, or linolenic acid supplemented, but not for bacteria grown with Tween 20. Overall, the results indicate that lipid oxidation and loss of membrane integrity are not the only or most important detrimental reactions which can occur during storage. By altering the fatty acid composition, it was also found that properties of oleic acid gave rise to more robust bacteria than more saturated or unsaturated fatty acids did. © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:799–807, 2015     

Effects of<Emphasis Type="Italic">Fomitopsis pinicola</Emphasis> extracts on antioxidant and antitumor activities

We investigated the effects ofFomitopsis pinicola extract on biological activity by examining the antioxidant and antitumor activityin vitro andin vivo. When theF. pinicola extract concentration was raised from 60 to 120 μg/mL, the DPPH scavenging rate increased from 50.3 to 88.2% and the superoxide anion radical scavenging rate increased from 45.2 to 85.3% when theF. pinicola extract concentration was raised from 500 to 700 μg/mL. After incubatingF. pinicola extract for 12 h, the linoleic acid scavenging rate increased from 35.5 to 90.5%. A similar finding was observed for butylated hydroxytoluene. The total phenolic content of theF. pinicola extracts were approximately 10- to 16-fold higher than what was observed in theP. nebrodensis andA. camphorate extracts. The glutathione production, using decoctions prepared fromF. pinicola, was 20.0 μM/g of liver, which corresponded to approximately 4.0-fold higher than the control. The glutathione peroxidase activity was 8.3 U/mg of protein, which was approximately 2.8-fold higher than the activity level observed in the control rat livers. The cell viability rates of all the human cancer cells, when 100 μg/mL of ethanol extract was used for the different types of cancer cells, decreased with increasing extract concentrations in comparison to the hot water extract. In particular, when HeLa and Hep3B cells were incubated with 1.000 μg/mL of methanol extract, the cell viability rates were 20 and 25%, respectively, which was approximately 3.0-fold higher than what was observed for the hot water extract. The first two authors contributed equally to this work.     

Garlic allyl derivatives interact with membrane lipids to modify the membrane fluidity

As a novel approach to the mode of medicinal action of garlic, its constituents were comparatively studied with respect to their interactions with membrane lipids to modify the membrane fluidity. Allyl derivatives rigidified tumor cell and platelet model membranes consisting of unsaturated phospholipids and cholesterol at 20–500 μM with the potency being diallyl trisulfide (DATS) > diallyl disulfide (DADS) by preferentially acting on the hydrocarbon cores of lipid bilayers. They were also effective in rigidifying candida cell model membranes prepared with ergosterol and phospholipids at 100–500 μM with the potency being DADS > DATS > diallyl sulfide (DAS), but not bacteria cell model membranes without ergosterol. Alliin, a precursor of these DASs, was not active on any membranes at 500 μM. Both relative intensity and selectivity in membrane effects correlated with those in antiproliferative, antiplatelet and antimicrobial effects. In cell culture experiments, membrane-active DASs inhibited the growth of tumor cells cultured for 24 and 48 h at 20–500 μM to show the potency being DATS > DADS, together with rigidifying cell membranes by acting on their deeper regions more intensively. However, membrane-inactive allyl derivatives were not growth-inhibitory on tumor cells. The membrane lipid interactions of DASs appear to be one of possible mechanisms underlying different effects of garlic.     

Biogenesis of microbial transport systems: evidnce for coupled incorporation of newly synthesized lipids and proteins into membrane

The biogenesis of the independent β-galactoside and β-glueoside transport systems of Escherichia coli K12 has been studied using an unsaturated fatty acid auxotroph. The response of transport rate to temperature was determined for cells grown with different fatty acid supplements. A change in the slope of an Arrhenius plot for transport rate was obtained at transition temperatures unique for each of the five fatty acid supplements tested. Both of the transport systems studied here had identical transition temperatures when the cells were grown with the same fatty acid supplement, indicating that the transport temperature characteristics are determined primarily by the properties of the lipid phase of the membrane.     

A serum-free,chemically-defined medium for function and growth of primary neonatal rat heart cell cultures

Summary A serum-free, chemically defined medium for supporting rhythmic contraction, maximum survival, and moderate growth of cardiac cells was achieved by using a combination of hormones and growth supplements in a mixture of equal volumes of Ham’s F12 and Dulbecco’s modified Eagle’s medium. The hormones and growth supplements included insulin, transferrin, selenium, fetuin, bovine serum albumin, hydrocortisone (HC),l-thyroxine (T₄), and epidermal growth factor (EGF). Cardiac cells were grown on fibronectin-precoated plates using the above serum-free medium. Cells grow in this medium exhibited a higher beating rate and were maintained for a longer time compared to those cells grown in serum. The effects of T₄, EGF, and HC on beating rate and survival time of both cultures of mixed cell population and enriched myoblast cell population were studied. In the enriched myoblast cell cultures grown in serum-supplemented medium, the beating rate ranged from 40 to 200 beats/min, and these cultures survived for 30 d. When these enriched cell cultures were grown in serum-free hormone-supplemented medium, the beating rate ranged from 190 to 240 beats/min, and these cultures survived for more than 90 d. These results show that some hormones affect growth, whereas others affect function.     

Spatial development of the cultivation of a bone marrow stromal cell line in porous carriers

The spatial development of the cultivation of a bone marrow stromal cell line (SR-4987) in porous carriers was investigated in order to construct a three-dimensional hematopoietic culture system. Low-rate continuous agitation, 20 rpm, was an appropriate method to achieve initial adhesion of cells onto a cellulose porous beads (CPB, 100 μm pore diameter) in a spinner bottle, compared with other methods such as centrifugation and intermittent agitation. Cell growth with continuous agitation at 70 rpm after initial cell adhesion was not inferior to that at 20 rpm. A 2- and 10-fold increase in the inoculum cell concentration for CPB and another type of porous cellulose beads (Micro-cube (MC), 500 μm pore diameter) resulted in a 1.2- and 2-fold increase in final cell concentrationm, respectively. Cells attached to the MC beads and a polyester nonwoven dic (Fibra-cell (FC)) could grow and spread well on the carriers and a fibroblast-like shape was observed under scanning electron microscopy while the cells on CPB were globular. The flatness and inner surface area of these carriers may be the reason for the differences in cell morphology. This revised version was published online in July 2006 with corrections to the Cover Date.     

Regulation of the Expression of the Photosynthetic Apparatus of Rhodobacter capsulatus Grown in Nitrogen-Limited Chemostat Cultures

Rhodobacter capsulatus was grown in chemostat cultures under different dilution rates and with ammonium ions as the limiting nutrient. The maximal growth rate (μmax) and the Monod cell growth saturation coefficient (K_s), were calculated from batch cultures grown at different concentrations of NH₄ ⁺. The experiments in chemostat were carried out at 0.25 mM (NH₄)₂SO₄, and the dilution rates were varied between 38% and 75% of μmax. The results indicated that under continuous culture conditions the cell yield coefficient (Y) (mg dry weight × μmol consumed ammonium sulfate⁻¹) decreased with increasing dilution rate (D). On the contrary, the cell yield was constant when expressed as mg cellular protein ×μmol consumed ammonium sulfate⁻¹. This occurred as a consequence of both an increase in the consumed ammonium sulfate and a simultaneous decrease in the cell biomass production at increasing growth rates. The cells produced at higher growth rates had a higher protein content per cell. The specific content of bacteriochlorophyll (Bchl) decreased (between 3 and 4 times) with increasing growth rates measured in either cells or chromatophores. However, the absorption spectra of the cells indicated that the ratio LHI (light-harvesting complex I) to LHII (light-harvesting complex II) Bchl complexes did not change. The reaction center (RC) complex content varied in parallel with the total Bchl content, yielding a constant photosynthetic unit of 65 mol Bchl × mol RC⁻¹ at different Ds. On the other hand, the uncoupled ATPase-specific activity measured in chromatophores was usually between 30% and 40% higher at the highest growth rates reached in these experiments. Received: 22 January 1996 / Accepted: 9 March 1996     

Evaluation of ultrafiltration membranes with biological macromolecules

Eighteen ultrafiltration membranes ranging in molecular weight cutoff ratings from 500 to 300,000 were tested with water, 0.5M NaCl solution, and, in some cases, with macromolecules and urea in a 3-in. stirred filter cell. Approximately half of the membranes showed a significant decrease in filtration rate during the first 24-hr period. The steady-state rates were less than the manufacturers' rating for about two thirds of the membranes, the discrepancy being greater for the membranes with high molecular weight cutoffs. The filtration rates were linearly dependent on applied pressure over the range at least as great as 15 to 55 psig. The rate decreased as the concentration of macromolecules such as transfer ribonucleic acid (tRNA) increased; the rate for a concentration of 3 mg tRNA/per ml was one-fourth of that observed when no tRNA was present. Some increase in rate (～33 to 50%) was obtained by increasing the stirring speed from 100 rpm to 1000 rpm. The membranes were effective for desalting and concentration of macromolecules but not for separation of large molecules from each other, such as tRNA from bovine serum albumin. Easily denatured molecules such as catalase were not deactivated by filtration at 4°C.     

Growth ofChlamydia psittaci strain menigopneumonitis in mouse L cells cultivated in a defined medium in spinner cultures

Summary L cells were grown in spinner cultures in a defined medium consisting of Waymouth medium MB752/1 (19) supplemented with 2 mg of fatty acid-free bovine serum albumin (BSA) per ml and 5 μg of oleate per ml (WO₅ medium). Growth in WO₅ medium was comparable to spinner L cell growth in two serum-containing media. The optimal concentration of oleate in the WO medium was 5 to 10 μg per ml. The use of 20 to 80 μg of oleate per ml of medium resulted in lower peak populations and earlier declines in viable cell counts. Cell death occurred rapidly in WO₁₆₀ medium. Cell growth in WO medium containing 5 to 80 μg of oleate per ml was well above the level of growth observed when no oleate was present in the medium. Since the total lipid and fatty acid compositions of the BSA used in this study have been characterized by the authors, the WO medium may be considered a defined medium. L cells have been continuously maintained in spinner cultures in WO₅ medium for over 50 passages with no major variation in the growth pattern. A 1000-fold increase inChlamydia psittaci strain meningopneumonitis, with a peak titer of 9.3×10⁷ plaque-forming units per ml, was observed when the chlamydial agents were grown in spinner L cells in WO₅ medium. This investigation was supported by Public Health Service Research Grant HE 08214 from the Program Projects Branch, Extramural Programs, National Heart and Lung Institute; The World Health Organization; and The Hormel Foundation.     

Regulation of ether lipids and their precursors in relation to glycolysis in cultured neoplastic cells

Tumors typically show high rates of glycolysis and elevated levels of ether lipids, particularly the alkyldiacylglycerols; thus, we investigated the relationship between ether lipid accumulation and glucose metabolism in a neoplastic cell line (B2-1). The B2-1 cells grown in 5.5 mM galactose in the absence of glucose produced very low levels of alkyldiacylglycerols, triacylglycerols, lactic acid, and dihydroxyacetone-P. Increasing concentrations of glucose caused a progressive increase in lactic acid, dihydroxyacetone-P, and up to a ten-fold increase in alkyldiacylglycerols and triacylglycerols. Glucose supplements also caused an increased incorporation of [9,10-3H]palmitic acid into alkyldiacylglycerols and triacylglycerols. These metabolic changes appeared to be independent of altered growth rates of the cells. The addition of hexadecanol along with glucose to the cultures resulted in a shorter lag and a more rapid rate of accumulation of alkyldiacylglycerols; hexadecanol supplements alone had no effect. The extent of uptake and oxidation of hexadecanol was similar in both the glucose and galactose-grown cells. These results indicate that the levels of alkyldiacylglycerols in neoplastic cells can be regulated by the extent their precursors are formed from glucose.     

Effect of mixing rate on beta-carotene production and extraction by dunaliella salina in two-phase bioreactors

beta-Carotene has many applications in the food, cosmetic, and pharmaceutical industries; Dunaliella salina is currently the main source for natural beta-carotene. We have investigated the effect of mixing rate and whether it leads to the facilitated release of beta-carotene from the cells of Dunaliella salina in two-phase bioreactors. Three pairs of bioreactors were inoculated at the same time, operated at 100, 150, and 170 rounds per minute, respectively, and illuminated with a light intensity of 700 micromol m(-2) s(-1). Each pair consisted of one bioreactor containing only aqueous phase for the blank and one containing the water phase together with dodecane, which is biocompatible with the cells. Comparison of the viability and growth of the cells grown under different agitation rates shows that 170 rpm and 150 rpm are just as good as 100 rpm. The presence and absence of the organic phase also has no influence on the viability and growth of the cells. In contrast to the growth rate, the extraction rate of beta-carotene is influenced by the stirrer speed. The extraction rate increases at a higher stirring rate. The effectiveness of extraction with respect to power input is comparable for all the applied mixing rates, even though it is slightly lower for 100 rpm than the others. The chlorophyll concentration in the organic phase remained very low during the experiment, although at higher mixing rates, chlorophyll impurity increased up to 3% (w/w) of the total extracted pigments. At 170 rpm carotenoid and chlorophyll undergo the highest extraction rate for both pigments-0.5% of the chlorophyll and 6% of the carotenoid is extracted.     

An improved plant regeneration system and ex vitro acclimatization of <Emphasis Type="Italic">Ocimum </Emphasis><Emphasis Type="Italic">basilicum</Emphasis> L.

An efficient, rapid and large scale propagation of a multipurpose herb, Ocimum basilicum through in vitro culture of nodal segments with axillary buds from mature plants has been accomplished. Among the cytokinins, 6-benzyladenine (BA), thidiazuron (TDZ), kinetin (Kin) and 2-isopentenyl adenine (2-iP) tested as supplements to Murashige and Skoog (MS) medium, 5.0 μM BA was optimum in inducing bud break. The highest rate of shoot multiplication was achieved on half-strength MS medium supplemented with 2.5 μM BA and 0.5 μM indole-3-acetic acid (IAA) combination. The shoots regenerated from TDZ supplemented medium when subcultured to hormone-free MS medium considerably increased the rate of shoot multiplication and shoot length by the end of third subculture. For rooting, MS medium supplemented with 1.0 μM indole-3-butyric acid (IBA) proved to be better than that supplemented with IAA or α-naphthalene acetic acid (NAA). The in vitro raised plantlets with well developed shoots and roots were successfully established in earthen pots containing garden soil and were grown in greenhouse with 90% survival rate. Chlorophyll a and b, carotenoids and net photosynthetic rate were measured in leaves during ex vitro acclimatization at 0, 7, 14, 21 and 28 days. Firstly these parameters showed a decreasing trend but subsequently increased after 7 days of acclimatization. These findings indicate that the adaptation of micropropagated plants to ex vitro conditions is more extended in time than generally accepted.     

Electron-spin resonance studies of lipid-modified microsomes from Friend erythroleukemia cells

The fatty acid composition of cultured Friend erythroleukemia cells was modified by supplementation of the medium with oleic or linoleic acid. There was a 30% reduction in saturated and a 35% reduction in polyunsaturated fatty acids in microsomal phospholipids when the cells were grown in media supplemented with oleic acid, and a 3-fold increase in polyunsaturated fatty acids when the cells were grown in linoleic acid-supplemented media. Electron-spin resonance studies with the 5-nitroxystearate probe demonstrated that there was no appreciable change in microsomal lipid mobility as measured by the order parameters. In contrast, changes in lipid mobility were detected with the spin-label probe when microsomes were first isolated from Friend erythroleukemia cells and subsequently modified by incubation with liposomes composed of either dioleoyl- or dilinoleoylphosphatidylcholine plus bovine liver phospholipid-exchange protein. The fatty acid compositional changes produced in these microsomes were similar to those obtained when the intact cells were grown in media containing supplemental fatty acids. These findings indicate that the lipid mobility of Friend cell microsomes can be altered by phospholipid replacements in vitro, but that this does not occur when similar microsomal fatty acid modifications are produced during culture of the intact cell.     

Damaging agitation intensities increase DNA synthesis rate and alter cell-cycle phase distributions of CHO cells

The effects of fluid-mechanical force (agitation) on the cell cycle kinetics of Chinese hamster ovary (CHO) cells cultured in suspension in 2-L bioreactors has been examined. A two-color flow cytometry method was used to determine the fraction rate of DNA synthesis. With increased agitation intensity, cell viability decreased as a result of increased cell death. However, increased agitation induced the viable cells of the culture to a higher proliferative state relative to a control culture. The fraction of viable cells of the high-agitation culture (250 rpm) in S phase was higher (up to 45%) and in G1 phase was lower (up to 50%) compared with the viable cells of the control culture (80 rpm). The DNA synthesis rate per viable S-phase cell of the high-agitation culture was confirmed by recovery experiments, which were conducted to measure the apparent specific growth rate and the cell cycle kinetics of the high-agitation culture upon reduction in the agitation rate from 250 rpm back to 80 rpm. The apparent specific growth rate of the test culture, calculated for the first 12 h of the recovery period, was greater than the apparent specific growth rate of the control culture. Furthermore, the proliferative state of the viable cells of the test culture, which had become higher relative to the control culture during the high agitation period, gradually approached the level of the control culture during recovery. Results also show that the magnitude of the agitation intensity; the culture agitated at 250 rpm attained a greater proliferative state than a parallel culture agitated at 235 rpm. The 250-rpm culture had a higher fraction of S-phase and a lower fraction of G1-phase cells than the 235-rpm culture. The DNA sunthesis rate per viable S-phase cell of the 250-rpm culture was greater than of the 235-rpm culture. (c) 1992 John Wiley & Sons, Inc.     

In vitro shoot multiplication and plantlet regeneration from nodal explants of <Emphasis Type="Italic">Cassia angustifolia </Emphasis>(Vahl.): a medicinal plant

An efficient, rapid and reproducible plant regeneration protocol was successfully developed for Cassia angustifolia using nodal explants excised from 14-day-old aseptic seedlings. Of the two cytokinins, 6-benzyladenine (BA) and thidiazuron (TDZ) evaluated as supplements to Murashige and Skoog (MS) medium, TDZ at an optimal concentration of 5.0 μM was effective in inducing multiple shoots. The highest rate of shoot multiplication was achieved on MS medium supplemented with 5.0 μM TDZ and 1.0 μM indole-3-acetic acid (IAA) at pH 5.8. The regenerated shoots when subcultured on hormone free MS medium considerably increased the rate of shoot multiplication and shoot length by end of fourth subculture passage. Rooting was achieved on the isolated shoots using MS medium with 60 μM indole -3- butyric acid (IBA) and 1% activated charcoal for 1 week and subsequently transferring the shootlets to half strength MS liquid media without IBA and activated charcoal. The in vitro raised plantlets with well-developed shoot and roots were successfully established in earthen pots containing garden soil and grown in greenhouse.