Simulating in ovulo osmotic potentials and O2 tensions normalize growth and pigmentation of immature cotton embryos

Liddiard, Vincent M.; Carman, John G.

doi:10.1007/s11240-010-9697-5

Cited by 2 publications

(10 citation statements)

References 30 publications

(46 reference statements)

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“…Even these plastids have a well developed thylakoid system, even if not so well developed as in the other two endosperm compartments. ROLLETSCHEK et al (2003) and LIDDIARD and CARMAN (2010) suggested that O2 production by photosynthetic activity in the seed could be necessary to provide O2 to the developing embryo, particularly if the seed coat acts as a barrier against the diffusion of this gas. Moreover the amount of functional chloroplasts in the seed of Eruca suggests that the photosynthetic product could be a relevant part of the carbohydrates necessary for the anabolic activity in the developing embryo.…”

Section: Discussionmentioning

confidence: 99%

Ultrastructural aspects of the embryo and different endosperm compartments, inEruca sativaHill cv. Nemat (Brassicaceae) during Heart and Torpedo stages

et al. 2010

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Vol. 63, no. 2: 197-210, 2010 The John Bingham Laboratory, NIAB. Huntingdon Road, Cambridge CB3 0LE, UK.Abstract -These observations are the fi rst on the ultrastructure of the embryo and the endosperm of Eruca sativa Hill. We investigated the cv. Nemat, which is characterized by a particularly high amount of lipids and glucosinolates. Our observations suggested that the thick and abundant micropylar endosperm, completely surrounding the suspensor, may be the main active source of nutrients for the embryo. This endosperm, like the central chamber endosperm, is particularly rich in functional chloroplasts and cellularizes later with respect to the other previously investigated Brassicaceae. The last (distal with respect to the embryo) suspensor cell exhibits important features related to the passage of nutrients, such as wall ingrowths. In fact these ingrowths appear as highly convoluted labyrinthine wall projections. Such ultrastructural features are typical of transfer cells. The accumulation stage in E. sativa cv. Nemat appears to occur early (Heart stage of embryo development, as Brassica napus). The endosperm compartment called Chalazal Endosperm Cyst (CEC), contributes actively to the embryo trophism during the Heart and Torpedo stages. This function is evident because of the high number of chloroplasts in the cyst and for the observed continuity between the CEC and the other endosperm compartments (CC endosperm and micropylar endosperm) in cv. Nemat. The morphology of the CEC appeared to be more similar to the pyriform shape sensu Brown et al., but with a more fl attened base with respect to the proposed examples, and without labyrinthine wall. The Chalazal Chamber appeared to be more similar to the Brown's type B in E. sativa. The presence of chloroplasts with a well developed thylakoid system indicates an active photosynthetic activity by the majority of the seed tissues. E. sativa leaves are normally harvested for food, while the seeds of cv. Nemat appear to be particularly rich in oil. The premature independence of seeds and fruits from the necessity of absorbing nutrients from the rest of the plant, could indicate the possibility of harvesting both leaves (earlier) and seeds (later) in this plant without compromising a full seed maturation.

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Section: Discussionmentioning

confidence: 99%

Ultrastructural aspects of the embryo and different endosperm compartments, inEruca sativaHill cv. Nemat (Brassicaceae) during Heart and Torpedo stages

et al. 2010

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“…Low O 2 tensions next to cultured embryos were established and maintained as in Liddiard and Carman (2010). In brief, this included the use of an autoclavable polycarbonate plastic culture chamber with gas inlet and outlet ports and an E-444 O 2 sensor (Remming Bio Instruments Co., Redfield, NY) that was attached to a CR-10 data logger (Campbell Scientific, Inc., Logan, UT).…”

Section: Methodsmentioning

confidence: 99%

“…The latter approach is becoming increasingly feasible because of advancements in chemical and biophysical measurement instrumentation of small samples (Murray 1963;Carman 1995;Otegui et al 2002;Carman et al 2005;Fuller et al 2009;Liddiard and Carman 2010). For the present study, we hypothesized that the routine regeneration of isolated cotton proembryos by direct embryogenesis in vitro could be accomplished by simulating the nutritional and hormonal requirements of embryony in situ.…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, we used enzyme-linked immunosorbent assays to determined levels of indole-3-acetic acid (IAA), six cytokinins, and abscisic acid (ABA) in ovule fluids during embryony (Hess et al 2002;Carman et al 2005;Fuller et al 2009). We also used microelectrodes, psychrometers, and osmometers to monitor in ovulo pH and osmotic potentials during embryony (Liddiard and Carman 2010). Finally, we used microelectrodes to monitor in ovulo O 2 tensions during embryony (Carman and Bishop 2004;Liddiard and Carman 2010).…”

Section: Introductionmentioning

confidence: 99%

“…We also used microelectrodes, psychrometers, and osmometers to monitor in ovulo pH and osmotic potentials during embryony (Liddiard and Carman 2010). Finally, we used microelectrodes to monitor in ovulo O 2 tensions during embryony (Carman and Bishop 2004;Liddiard and Carman 2010). Based on these analyses, we have constructed chemically defined media and unique culture equipment that better simulate the physicochemical environment of the cotton ovule.…”

Section: Introductionmentioning

confidence: 99%

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Improving cotton embryo culture by simulating in ovulo nutrient and hormone levels

Fuller

Liddiard

Hess

et al. 2011

In Vitro Cell.Dev.Biol.-Plant

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Plant ovules provide zygotes with a physicochemical environment that supports embryo differentiation, growth, and maturation. The exact nature of this embryogenesis-enabling environment is not well characterized, as evidenced by failed attempts to induce normal embryony from zygotes or proembryos (precotyledonary) on defined media. To identify factors required for cotton (Gossypium hirsutum L.) zygotic embryony in vitro, we previously performed chemical and dissolved oxygen tension analyses of cotton ovule fluids and tissues at multiple stages of embryony in situ. Based on these analyses, we report herein the development of procedures that normalize embryo differentiation, growth, maturation, and germination in vitro, starting with proembryos. Our medium differed from Murashige and Skoog (MS) medium as follows (percentage of MS): N (30%, mostly from ten amino acids), P (815%), K (237%), Mg (85%), Ca (267%), S (506%), Fe (88%), and myoinositol (883%). Levels of other MS nutrients and vitamins, except sucrose, were kept at MS levels. Additionally, we included 100 mg L −1 casein hydrolysate plus the following (mmol L −1 ): D-glucose (1.8), fructose (4.7), sucrose (62.0), arabinose (7.1), melibiose (3.5), malic acid (11.6), and citric acid (3.8).Mannitol was added to achieve a medium osmotic potential of −1.10 MPa, and an atmospheric O 2 tension of 3.3 mol m −3 at the surface of embryos was maintained during culture. When cultured on medium containing 8.0 μmol L −1 indole-3-acetic acid, 80-90% of proembryos (as small as 100 cells) of cultivars HS-26 and B-27 increased four-to eightfold in surface area during the first 18 d in culture and germinated thereafter to produce viable plants. Increases in surface area of proembryos cultured on a modified MS medium previously used for somatic embryogenesis were from 0.2-to 0.6-fold. The described embryo culture medium should be useful for studying nutritional and molecular aspects of early embryony and possibly for plant zygote transformation protocols.

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Simulating in ovulo osmotic potentials and O2 tensions normalize growth and pigmentation of immature cotton embryos

Cited by 2 publications

References 30 publications

Ultrastructural aspects of the embryo and different endosperm compartments, inEruca sativaHill cv. Nemat (Brassicaceae) during Heart and Torpedo stages

Ultrastructural aspects of the embryo and different endosperm compartments, inEruca sativaHill cv. Nemat (Brassicaceae) during Heart and Torpedo stages

Improving cotton embryo culture by simulating in ovulo nutrient and hormone levels

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