Callus cultures and bark from Norway spruce clones show similar cellular features and relative resistance to fungal pathogens

In field experiments, clones of Norway spruce [Picea abies (L.) Karst.] showed different degrees of resistance against pathogenic fungi inoculated into the bark that correlate with differences in polyphenolic parenchyma (PP) cells of the bark. Cells of spruce callus cultures, particularly towards the callus surface, resemble PP cells and this study looks at changes in callus cells during infection and the relative resistance of cultures from clones of low (weak) or high (strong) resistance to fungal infection. Callus cultures, initiated from trees with different resistance, were co-inoculated with Ceratocystis polonica (Siem.) C. Moreau and Heterobasidion annosum (Fr.) Bref. Callus cells from strong clones resemble PP cells of bark tissue from strong clones, having more polyphenolic bodies, while callus cells from weak clones are more similar to PP cells from those clones, which have less extensive phenolic bodies. Callus cultures from trees with weak resistance were more quickly overgrown by both species of pathogenic fungi than cultures from trees with strong resistance. Callus cells of infected cultures showed changes similar to activated PP cells of bark, including enhanced accumulation of polyphenolics. Phenolic bodies were more numerous and more extensive (larger and denser) in callus cells of strong versus weak clones under all conditions. Thus, callus cells may perform similar functions in defense as PP cells in the bark. Callus from trees of varying resistance seem to reflect the relative resistance of the trees from which they are derived, and this study indicates that some mechanisms of resistance can be studied using callus from trees of different resistance.     

Biochemical parameters to assess cell differentiation of Bouvardia ternifolia Schlecht callus

Calli derived from leaves and radicles of B. ternifolia were grown on Murashige and Skoog (MS) basal medium, and the effects of different nitrogen sources on the rate of callus growth and on the enzymes related to nitrogen assimilation were studied. Ammonium alone did not support callus growth unless a Krebs-cycle intermediate was added to the medium. The activities of glutamine synthetase (EC 6.3.1.2), glutamate synthase (EC 1.4.7.1), and glutamate dehydrogenase (EC 1.4.1.2) were measured in homogenates of callus grown on media supplied with different nitrogen sources. The results indicate that leaf and root calli have similar levels of these enzymes when grown on MS medium (Murashige and Skoog 1962. Physiol. Plant. 15, 473–497). However, when the calli were supplied with glutamine as the sole nitrogen source, the activity of glutamate synthase increased in leaf callus but was almost completely inhibited in root callus. The results indicate that calli originated from different B. ternifolia tissues do not have the same biochemical dedifferentiated state.     

Expression of nodule-specific uricase in soybean callus tissue is regulated by oxygen

In soybean root nodules the enzyme uricase is expressed concomitantly with nodule development. The initial expression of this protein does not depend on active nitrogen fixation, as demonstrated by analysis of uricase activity in effective and ineffective root nodules. However, the maximal level of uricase activity is determined by the infecting Rhizobium japonicum strain. Sterile root cultures and callus tissue, devoid of the microsymbiont, were incubated at varying oxygen concentrations and analyzed for uricase activity. The specific activity of uricase was increased by lowering the oxygen concentration, with the highest activity obtained around 4−5% oxygen. The increase in uricase activity was due to increased uricase synthesis, as demonstrated by in vivo labelling of callus culture followed by immunoprecipitation with antibodies raised against highly purified nodule uricase.     

Growth and infectivity of callus cultures of tomato plants infected with a mycoplasma disease — Potato witches' broom

Callus tissues were derived from the stem of healthy tomato plants (Lycopersicum esculentum Mill. ev. Pr?honické) and of plants infected with potato witches' broom—a disease caused by mycoplasma. Callus cultures were established on modified fully synthetic media described byMorel (1948) and byMurashige andSkoog (1962). Callus cultures obtained from diseased plants were grown and subcultured on both media, growth in primary isolates from healthy plants took place on the Murashige and Skoog medium only. Growth of callus tissue derived from diseased plants was more vigorous even after several subcultivations in comparison with callus tissues isolated from healthy plants. Variations in the morphology in these callus cultures were not noted. Callus cells of diseased plants varied in size; they were about 50% larger than those from healthy ones. Implantation of primary and subcultivated callus tissues into tomato stems of healthy plants did not show any symptoms of infection on test plants.     

Role of origin and endophyte infection in browning of bud-derived tissue cultures of Scots pine (Pinus sylvestris L.)

Callus tissues originating from buds of mature Scots pine (Pinus sylvestris L.) trees exhibit the typical problem of browning, which leads to degeneration and death of the tissues. The effects of medium, origin (tree and location) and endophyte infection were studied on the browning and growth of bud-derived tissue cultures. The calli growing on medium with higher kinetin content and source of organic nitrogen, and originating from the southern location grew better and exhibited less browning. Endophytic microbial cells were detected in the brown callus tissues by transmission electron microscopy. The natural endophyte infection frequency of Scots pine buds was studied and found dependent on the tree, but not on the location. A well-growing, green callus line was artificially infected by an endophytic strain of Methylobacterium extorquens, and browning was not observed on solid media compared to the uninfected control clones of the same callus. However, suspension cultures started from the infected callus died faster than cultures started from the uninfected callus. The endophyte species composition and plant genotype together with tissue culture conditions are the key factors for gaining plant tissue cultures with high regeneration capacity.     

Nitrogen Assimilating Enzyme Activities and Enzyme Protein during Development and Senescence of Effective and Plant Gene-Controlled Ineffective Alfalfa Nodules

Effective (N₂-fixing) alfalfa (Medicago sativa L.) and plant-controlled ineffective (non-N₂-fixing) alfalfa recessive for the in₁ gene were compared to determine the effects of the in₁ gene on nodule development, acetylene reduction activity (ARA), and nodule enzymes associated with N assimilation and disease resistance. Effective nodule ARA reached a maximum before activities of glutamine synthetase (GS), glutamate synthase (GOGAT), aspartate aminotransferase (AAT), asparagine synthetase (AS), and phosphoenolpyruvate carboxylase (PEPC) peaked. Ineffective nodule ARA was only 5% of effective nodule ARA. Developmental profiles of GS, GOGAT, AAT, and PEPC activities were similar for effective and ineffective nodules, but activities in ineffective nodules were lower and declined earlier. Little AS activity was detected in developing ineffective nodules. Changes in GS, GOGAT, AAT, and PEPC activities in developing and senescent effective and ineffective nodules generally paralleled amounts of immunologically detectable enzyme polypeptides. Effective nodule GS, GOGAT, AAT, AS, and PEPC activities declined after defoliation. Activities of glutamate dehydrogenase, malate dehydrogenase, phenylalanine ammonia lyase, and caffeic acid-o-methyltransferase were unrelated to nodule effectiveness. Maximum expression of nodule N-assimilating enzymes appeared to require the continued presence of a product associated with effective bacteroids that was lacking in in₁ effective nodules.     

Production of salidroside and tyrosol in cell suspension cultures of Rhodiola crenulata

Salidroside and its aglycone tyrosol are important compounds found in Rhodiola plants. In this study, callus derived from Rhodiola crenulata was induced and grown when explants were incubated on a Murashige and Skoog (MS) medium containing various concentrations of 6-benzyaldenine (BA), naphthalene acetic acid (NAA) and thidiazuron (TDZ). Callus was easily initiated from juvenile leaves in half strength MS medium supplemented with 0.5 mg/L BA and 3.0 mg/L NAA, while full strength MS containing 0.5 mg/L TDZ and 0.5 mg/L NAA was the best for callus subculture and subsequent cell suspension culture. The activities of l-phenylalanine ammonia lyase (PAL) and β-d-glucosidase, two key enzymes in salidroside synthesis, increased at first and subsequently decreased in cell suspension cultures. The salidroside and tyrosol levels in the cell suspension cultures were determined using high-performance liquid chromatography. High levels of salidroside and tyrosol were detected in cell suspension cultures of R. crenulata extracted with 75 % methanol, demonstrating that the biotechnological production of these compounds using plant cell suspension cultures derived from R. crenulata may be an attractive alternative to harvest-based production.     

Auxin activity of phenylacetic acid in tissue culture

The ability of phenylacetic acid (PAA), a naturally occurring auxin, to initiate and support growth of callus and suspension cultures of several species is reported. Callus tissue of tobacco (Nicotiana tabacum L. var. WI-38), initiated and maintained on a medium with 2,4-dichlorophenoxyacetic acid (2,4-D), was transferred to and maintained on media supplemented with 25–500 μM PAA as the only plant growth regulator (PGR). Optimal concentrations of PAA were determined for tobacco callus proliferation in the dark (250 μM PAA) and with a 16-h light/8-h dark photoperiod (500 μM PAA). Tobacco suspension cultures were maintained for over 28 transfers in media containing 20–40 μM PAA as the sole PGR. When tobacco callus tissue maintained on PAA-supplemented media for over 18 months was transferred to liquid media containing kinetin, plantlets were regenerated. Callus of sunflower (Helianthus annuus L. var. Russian Mammoth) proliferated on media containing PAA at 5–250 μM as the sole PGR. Similar PAA concentrations inhibited normal development and promoted callus formation in tobacco and pea (Pisum sativum L. vars. common, Frogel, and Frimas) epicotyl tissue. PAA as the sole PGR did not support the growth of soybean (Glycine max (L.) Merrill var. Fiskeby) callus or suspension cultures. Chickpea (Cicer arietinum L. var. UC-5) and lentil (Lens culinaris Medic. var. Laird) callus cultures proliferated on media containing 25–500 μM PAA, but habituation of the cultures was common. PAA was not toxic to tobacco, chickpea, and lentil tissues at levels as high as 500 μM.     

Hormonal Regulation of the Lectin Biosynthesis in Callus Culture of the Phaseolus vulgaris Plant

Callus cultures established from Phaseolus vulgaris seedlings were used to investigate hormonal influence on lectin biosynthesis. The plant tissue cultures were initiated using defined levels of both a cytokinin (kinetin) and an auxin (2,4-dichlorophenoxyacetic acid) and were then transferred to media containing different amounts of these hormones. The lectin content of each callus culture was determined using an enzyme immunoassay specific for the seed lectin of the P. vulgaris plant. The lectin biosynthesis was directly affected by the levels of auxin and cytokinin in the culture media and no lectin was detected in hormone-free medium. This enabled us to compose culture media yielding a maximal or minimal lectin content of the callus cultures, illustrating the ability to induce an enhancement or suppression of the in vitro lectin biosynthesis. The lectin level of callus tissue during the growth cycle of a culture was, furthermore, related to the cellular growth rate which might indicate an involvement of the lectin in cellular events during rapid cell division.     

Response of light- and dark-grown callus of atrazine-resistant and susceptible rapeseed (Brassica napus) to varying concentrations of atrizine

Callus cultures initiated with tissue of triazine-resistant and susceptible lines of Brassica napus L. were cultured in the presence of atrazine (10^-5 to 10^-4 M) under a 16-h photoperiod or in continuous darkness. On atrazine-free media callus growth was characteristically greater for the light-grown cultures. On media containing atrazine, growth of callus from triazine-resistant and susceptible rapeseed cultured in the dark did not differ significantly. Addition of atrazine to the culture medium resulted in a significant reduction in the growth of light-grown callus of the susceptible genotype to a level equivalent to that of the dark-grown cultures. Atrazine had no effect on the growth of light-grown callus initiated with triazine-resistant rapeseed.     

Analysis of capsaicinoid biosynthesis pathway genes expression in callus cultures of Capsicum chinense Jacq. cv. ‘Umorok’

The placental tissue of the highly pungent chilli cultivar, Capsicum chinense Jacq. cv. ‘Umorok’, is used as explants for callus induction. Callus cultures were subcultured after every 32 days and growth curves for a period of six consecutive growth cycles were studied till a stable capsaicinoids producing callus cultures were obtained. The capsaicinoids content in placental tissue explants decreased gradually during the first 2 months of culture as the explants dedifferentiated to form friable callus while the biomass and capsaicinoid content did not show much change in the subsequent growth cycles. The maximum callus biomass of 7.8 g freshweight (FW) or 0.56 g dry weight (DW) per culture were obtained on the 24th day of every growth cycle and the maximum average capsaicinoids content (1.6 mg g^?1 FW capsaicin and 0.78 mg g^?1 FW dihydrocapsaicin) were obtained on the 20th day of every growth cycle. To investigate the underlying dynamics for capsaicinoid biosynthesis during callus formation, comparative gene expression analysis of the genes involved in capsaicinoid biosynthesis pathway were also studied by qRT-PCR analysis. When compared with placental tissue, all the studied genes showed reduced expression during callus formation, especially putative aminotransferase (pAMT) and pungent gene 1 (Pun1), which were extensively down regulated from the 3rd month onwards in the callus cultures. Therefore, the present study revealed that the down-regulated expression of mainly two putative genes in capsaicinoid biosynthetic pathway (pAMT and Pun1) resulted in lower accumulation of capsaicinoids in callus cultures compared to placental tissues of fruits.

     

The Effect of Growth Conditions and Origin of Tissue 5Phaseolus vulgaris L.)

Callus cultures isolated from various somatic tissues and anthertissue of Phaseolus vulgaris seedlings on a defined growth mediumcontained few diploid cells. The proportion of diploid cellsdid not alter as cultures lost their ability to form vasculartissue. Meristematic cells of roots initiated after transferto induction medium were diploid. All cultures lost their morphogeneticpotential after five to seven subcultures except anther calluswhich formed vascular tissue over a prolonged period of cultureon maintenance medium. After six subcultures anther callus containedmore polyploid cells than somatic cultures. Callus isolated from bean hypocotyl tissue in the presence ofcoconut milk consisted mainly of diploid cells and retainedits morphogenetic potential for a greater number of subculturesthan callus grown on defined medium. Transfer of callus isolatedon the defined medium to medium containing coconut milk increasedthe proportion of diploid cells and prevented further loss ofinorphogenetic potential. An equivalent concentration of cytokininto that in coconut milk prevented the loss of potential butdid not affect the ploidy of the cultures.     

DIFFERENCES IN NITROGEN REQUIREMENTS OF TWO CLONES OF CONVOLVULUS ARVENSIS IN VITRO

Various nitrogen sources were shown to alter the growth and modify nitrate reductase activities of stem callus tissue derived from two clones of Convolvulus arvensis L. (field bindweed). Callus from a Washington (S) clone grew better and had a higher level of nitrate reductase activity than callus from a New Mexico (R) clone when nitrate was the only source of nitrogen available in the culture medium. The addition of glycine to the culture medium decreased growth of the R clone and increased growth of the S clone, but glutamic acid repressed growth of both clones. An amide source of nitrogen such as glutamine or asparagine, or ammonium was required to produce maximum growth of both bindweed clones. Glutamine increased nitrate reductase activity in the two clones, and glycine increased nitrate reductase activity in the S clone but decreased it in the R clone. Glutamic acid decreased nitrate reductase activities in both the R and S tissues.     

Development of haploid cell lines from immature barley,Hordeum vulgare,embryos

Callus and suspension cell lines were derived from haploid barley embryos produced by the Bulbosum method. Embryos 1 to 2 mm long callused on medium containing a low concentration of 2,4-dichlorophenoxyacetic acid (2,4-D). Fast-growing nodular, beige callus (Type 1), slow-growing, light brown, watery callus (Type 2) and a dense, light yellow, nodular callus (Type 3) were recovered. Type 3 callus was embryogenic and was produced on embryos 1 to 2 mm in length. Although callus cultures gradually became polyploid, a small proportion of haploid cells was retained and the majority of regenerated plantlets were haploid. The organogenic potential of long-term (Type 1) callus cultures was generally low and decreased with time. Attempts to inducede novo shoot formation in Type 1 cultures were not successful.     

Chromosomal instabilities in callus tissue from haploid barley (Hordeum vulgare L.)

Callus culture was derived from haploid barley embryos after crossing withHordeum bulbosum. The callus tissue is cytologically heterogeneous, containing haploid, diploid and polyploid cells. Aneuploidy and karyokinetic irregularities were also observed. Some problems of chromosomal instabilities in plant tissue cultures are discussed.     

Plant regeneration from somatic embryos in black pepper

Embryogenic callus derived from zygotic embryos of black pepper (Piper nigrum Linn.) were induced to form somatic embryos on solid and liquid Schenk and Hildebrandt basal medium. Callus proliferation, somatic embryo-genesis and germination of embryos were achieved in about 8 months in static cultures while it took only 8 weeks in liquid suspension cultures. The highest number of embryos and plantlets was produced from cells grown as suspension cultures raised in half-strength medium without growth regulators and sucrose level reduced from 3% to 1.5%. Regenerated plants were established in soil.     

Medium composition and methyl jasmonate influence the amount and spectrum of secondary metabolites in callus cultures of Zanthoxylum stenophyllum Hemsl.

Callus cultures of Zanthoxylum stenophyllum were initiated in vitro and the effect of growth regulators and elicitors was tested both upon callus growth and secondary metabolite production. On a medium containing naphthaleneacetic acid, kinetin, and 2,4-dichlorophenoxyacetic acid, a yellowish and friable callus was obtained from 90% of cotyledon explants. Callus growth and secondary metabolite accumulation was followed after sub-culturing the established callus culture on different media containing various hormonal combinations. Results indicate that medium containing naphthaleneacetic acid and a higher concentration of 2,4-dichlorophenoxyacetic acid gave the highest stimulation of growth. Addition of an organic nitrogen source also had a positive effect on growth. Rapid HPLC screening of methanol extractable secondary metabolites from calluses showed that phytohormones and nutrients were able to modify the chromatographic pattern of compounds. Calluses grown on the medium giving the highest stimulation of growth show a reduced accumulation of some secondary products, but not all. In response to elicitation by methyl jasmonate, metabolite production was different for the different classes of compounds, and hormonal composition of the culture medium influenced the response. Thus, results confirm the importance of the reciprocal interactions between hormones, nutrients, and elicitors when attempts are made to enhance secondary metabolite accumulation in in vitro cultures.     

Morphogenetic Investigations in Callus Cultures of Tylophora indica

Callus cultures derived from stem explants of Tylophora indica (Fam. Asclepiadaceae) show a broad spectrum of tissue differentiation and regenerative potentialities over a wide range of nutrient conditions resulting in the production of roots, shoots, bipolar embryos and plantlets. This has been investigated and interpreted on a histological basis. Studies on the morphogenesis of embryos have shown that only such embryonal cells which were deeply embedded with in the callus parenchyma showed an ontogenic development reminiscent of ovular embryogeny whereas in those organized in the superficial layer of the callus the sequence of embryogeny was entirely different. Free cells growing in agitated liquid media first developed into filamentous structures and eventually, by repeated intercalary divisions, organized into bipolar embryos. Development of accessory embryos through cleavage and budding in the callus, differentiation of amphicribral vascular nodules, and meristematic colonies organized into spheres of parenchyma were also observed. These alternative morphogenetic events probably reflect the biochemical subtleties occurring within the callus as a result of an inadequacy or an imbalance of the various constituents in the culture medium.     

A genetic analysis of cell culture traits in tomato

Summary Tomato genotypes superior in regenerating plants from protoplast and callus cultures were obtained by transferring regeneration capacity from Lycopersicon peruvianum into L. esculentum by classical breeding. The genetics of regeneration and callus growth have been studied in selfed and backcross progenies of a selected plant (MsK93) which has 25% L. peruvianum in its ancestry. Segregation data showed that the favourable cell culture traits of L. peruvianum are dominant. Regeneration capacity from established callus cultures was controlled by two dominant genes. Callus growth on primary expiants, callus growth of established cultures and shoot regeneration from explants had high heritabilities (0.47, 0.78, 0.87, respectively). Callus growth and regeneration capacity were not correlated within the populations studied.     

Establishment of Aster sedifolius and Aster caucasicus callus cultures as a potential source of antioxidants

Abstract

Callus cultures were established for Aster sedifolius and Aster caucasicus, two Aster species used in natural medicine for their anticancer, antibacterial and antiviral activities attributed to the high content of antioxidant compounds such as polyphenols and ascorbate. The effects of growth medium and light condition on the induction and growth rate of callus from leaf, petiole and root explants are reported. Callus induction and proliferation depended on the genotype and the experimental conditions. In particular, a profuse callus culture was obtained from leaf explants grown in the light on medium supplemented with 2,4-D (0.1 mg l^?1) for A. caucasicus and on medium supplemented with 2,4-D (0.44 mg l^?1) plus 6-benzil-ammino-purine (BAP) (0.22 mg l^?1) for A. sedifolius. The content of total polyphenol and ascorbic acid was estimated in leaf and petiole explants of in vivo plants and in the relative derived calli. In calli, polyphenol content was lower than in the corresponding in vivo organs. Furthermore, the total ascorbic acid content decreased in calli while the reduced ascorbic acid pool increased. These findings demonstrate that Aster callus cultures produce antioxidant compounds and as such might be a model system to investigate the regulation and production of these important metabolites.