Meiotic transmission of epigenetic changes in the cell-division factor requirement of plant cells

During the development of tobacco plants, cells undergo epigenetic changes that alter their requirement in culture for the cell-division factor cytokinin. Cultured leaf cells alternate between cytokinin-requiring (C-) and cytokinin-independent (C+) states at extremely high rates of approximately 10-2 per cell generation by a process called pseudodirected variation. Here we show that plants regenerated from most C+ clones express the Habituated leaf (Hl) trait, i.e., leaf tissues exhibit the C+ phenotype rather than the wild-type C- phenotype in culture. This new trait then segregates as a monogenic dominant trait indicating that conversion of C- cells to C+ cells is associated with a meiotically transmissible, genetic modification. Two independent mutants, Hl-2 and Hl-3, derived from C+ variants arising in culture were unstable in planta and reverted gametically at rates roughly comparable to pseudodirected variation in culture. Cells of the Hl-2 mutant, but not of a stable Hl-1 mutant, reverted phenotypically at high rates in culture. This revertant C- phenotype persisted in some plants regenerated from cloned revertant lines, and then showed irregular segregation in two successive sexual generations. These results show for the first time that meiotically transmissible epimutations can occur reversibly and at high rates in culture.     

Reversible, cell-heritable changes during the development of tobacco pith tissues

Cytokinin requiring cells of Nicotiana tabacum L. cv "Havana 425" can be induced in culture to become cytokinin autotrophic. This process is known as cytokinin habituation. Earlier we showed that pith parenchyma tissue consists of inducible cells, which habituate at high rates when treated with cytokinin, and noninducible cells, which remain cytokinin requiring under these conditions. The inducible and noninducible phenotypes are determined states that arise during the development of the tobacco plant and are inherited by individual cells. Here we show that pith tissue of plants regenerated from cloned lines of noninducible cells exhibits the inducible phenotype indicating that noninducible cells, or their descendants, can become inducible. This change in competence for habituation appears to have an epigenetic basis; it is reversible, occurs at high rates, and depends on the developmental state of the cells. The habituated state occurs in two forms that can be distinguished by their difference in developmental potential. Habituated cells derived from inducible pith cells give rise to normal plants whose leaf and pith tissues require cytokinin for growth in culture. In contrast, habituated cells obtained by transferring noninducible cells on media with progressively lower cytokinin concentrations give rise to plants whose leaf and pith tissues exhibit a cytokinin-habituated phenotype in culture.     

Evidence for a Mendelian factor controlling the cytokinin requirement of cultured tobacco cells

Cultured leaf tissues of Nicotiana tabacum L. cv. “Havana 425” normally require an exogenous source of cytokinin for rapid growth; stem-cortex tissues do not—ie, they exhibit the cytokinin-habituated phenotype. We found that plants regenerated from cloned cortex and leaf tissues from one particular plant differed in leaf-tissue phenotype: Leaf tissues derived from leaf cells exhibited the normal, nonhabituated phenotype, whereas leaf tissues derived from cortex cells were cytokinin-habituated. This difference in leaf phenotype was not found using leaf and cortex cells from six other donor plants. The inheritance of the habituated leaf trait was studied in tissues from cortex-derived plants and hybrids between these plants and normal plants. F₁ hybrids were intermediate between the parental types in degree of habituation. No differences were found between reciprocal hybrids. These results suggest that the habituated leaf trait is an incompletely dominant, nuclear trait. Both parental and intermediate phenotypes were recovered in the F₂ progeny. The frequency of habituated leaf progeny in the F₂ and backcross populations provide evidence that the trait is regulated at a single genetic locus.     

Hormonal regulation of zeatin-riboside accumulation by cultured tobacco cells

Auxin (11 M -naphthaleneacetic acid) and cytokinin (1.4 M kinetin) regulate cytokinin accumulation by cytokinin-requiring (C^-) and cytokinin-autotrophic (C⁺) lines of Havana 425 tobacco (Nicotiana tabacum L.) tissues. No trans-zeatin riboside (ZR) (<0.5 pmol·g^-1 fresh weight) was detected in six C^- and nine C⁺ lines grown for 14 d on auxin + cytokinin and auxin medium, respectively. C⁺ lines, but not C^- lines accumulated ZR (1.9–5.1 pmol·g^-1 fresh weight) when incubated on hormone-free medium but both lines accumulated ZR when incubated on kinetin medium. Therefore, it appears that kinetin treatment can induce ZR accumulation and that this accumulation is blocked by auxin treatment. Similar effects were obtained with some lines of cells autotrophic for both auxin and cytokinin. Tobacco plants carrying the dominant Habituated leaf-1 allele (Hl-1) differ from wild-type plants in that leaf-derived tissues in culture exhibit a C⁺ phenotype. No differences in ZR content were found in C⁺ leaf tissues from Hl-1/Hl-1 plants and C⁺ tissues that arise epigenetically in wild-type plants. This indicates that the H-1 allele does not act to induce overproduction of ZR. The Hl-1 allele is known to have oncogenic functions similar to the isopentenyl transferase (ipt) locus of the Ti plasmid. Although Hl-1/Hl-1 cells transformed with Ti plasmids defective at the ipt locus are tumorigenic and hormone-autotrophic in culture, they contain low levels of ZR typical of non-transformed Hl-1/Hl-1 cells. Therefore, the high levels of ZR characteristics of cells transformed with wild-type Ti plasmids are not necessary for expression of the tumor phenotype.Abbreviations C^- cytokinin-requiring phenotype - C⁺ cytokinin-autotrophic phenotype - Hl-1 habituated leaf-1 locus - IPA isopentenyladenosine - ipt isopentenyltransferase gene - ZR trans-zeatin riboside     

Transdetermination of plant cells

Tissues derived from the leaf lamina of Nicotiana tabacum L. cv. Havana 425 plants require cytokinin for continuous proliferation in culture, whereas tissues derived from the cortex of the stem are cytokinin autotrophic. Both phenotypes persist when the two types of cells are cloned, indicating that leaf- and cortex-derived cells are determined to express different cytokinin requirements in culture. We showed that cultures derived from leaf and cortex tissues of plants regenerated from cloned leaf and cortex cells exhibit the cytokinin requirement of comparable tissues of seed-grown plants. This provides direct evidence that plant cells can undergo transdetermination and that this process has an epigenetic basis.     

amp1 - a mutant with high cytokinin levels and altered embryonic pattern, faster vegetative growth, constitutive photomorphogenesis and precocious flowering

amp1 , a mutant of Arabidopsis thaliana has a phenotype altered in three different aspects of plant development; spatial pattern, photomorphogenetic growth, and initiation of flowering. While fewer than 0.1% of the seedlings of wild-type plants are non-dicot as many as 20% of the seedlings of the amp1 mutant are tricot or tetracot. The rate of leaf initiation is faster and vegetative phyllotaxy is altered in amp1 . When grown in the dark amp1 seedlings show morphogenetic properties similar to light-grown wild-type plants: they do not form an apical hook, have hypocotyls shorter than wild-type plants and form etiolated true leaves. amp1 mutant flowers significantly earlier than congenic Amp1 plants. The mutant has six times more cytokinin than wild-type suggesting that endogenous cytokinin levels might play an important role in mediating these different developmental processes. AMP1 might code for a negative regulator of cytokinin biosynthesis, or may be required for the degradation of cytokinin.     

AUXIN RESPONSE FACTORS 6 and 17 control the flag leaf angle in rice by regulating secondary cell wall biosynthesis of lamina joints

Flag leaf angle impacts the photosynthetic capacity of densely grown plants and is thus an important agronomic breeding trait for crop architecture and yield. The hormone auxin plays a key role in regulating this trait, yet the underlying molecular and cellular mechanisms remain unclear. Here, we report that two rice (Oryza sativa) auxin response factors (ARFs), OsARF6 and OsARF17, which are highly expressed in lamina joint tissues, control flag leaf angle in response to auxin. Loss-of-function double osarf6 osarf17 mutants displayed reduced secondary cell wall levels of lamina joint sclerenchymatous cells (Scs), resulting in an exaggerated flag leaf angle and decreased grain yield under dense planting conditions. Mechanical measurements indicated that the mutant lamina joint tissues were too weak to support the weight of the flag leaf blade, resembling the phenotype of the rice increased leaf angle1 (ila1) mutant. We demonstrate that OsARF6 and OsARF17 directly bind to the ILA1 promoter independently and synergistically to activate its expression. In addition, auxin-induced ILA1 expression was dependent on OsARF6 and OsARF17. Collectively, our study reveals a mechanism that integrates auxin signaling with the secondary cell wall composition to determine flag leaf angle, providing breeding targets in rice, and potentially other cereals, for this key trait.

Two auxin response genes influence the secondary cell wall biosynthesis and the strength of lamina joints, thereby contributing to the adjustment of flag leaf angles.     

Senescence-Inducible Expression of Isopentenyl Transferase Extends Leaf Life, Increases Drought Stress Resistance and Alters Cytokinin Metabolism in Cassava

Cassava (Manihot esculenta Crantz) sheds its leaves during growth, especially within the tropical dry season. With the production of SAG12-IPT transgenic cassava we want to test the level of leaf retention and altered cytokinin metabolism of transgenic plants via the autoregulatory senescence inhibition system. After confirmation of transgene expression by molecular analysis and phenotype examination in greenhouse plants, two transgenic plant lines, 529-28 and 529-48, were chosen for further investigation. Detached mature leaves of 529-28 plants retained high levels of chlorophyll compared with wild-type leaves after dark-induced senescence treatment. Line 529-28 showed significant drought tolerance as indicated by stay-green capacity after drought stress treatment. Field experiments proved that leaf senescence syndrome was significantly delayed in 529-28 plants in comparison with wild-type and 529-48 plants. Physiological and agronomical characterizations of these plants also revealed that the induced expression of IPT had effects on photosynthesis, sugar allocation and nitrogen partitioning. Importantly, the 529-28 plants accumulated a high level of trans-zeatin-type cytokinins particularly of corresponding storage O-glucosides to maintain cytokinin homeostasis. Our study proves the feasibility of prolonging the leaf life of woody cassava and also sheds light on the control of cytokinin homeostasis in cassava leaves.     

The "drought-inducible" histone H1s of tobacco play no role in male sterility linked to alterations in H1 variants

Tobacco ( Nicotiana tabacum L.) has two major H1 variants (H1A and H1B), which account for over 80% of chromatin linker histones, and four minor variants: H1C, H1D, H1E and H1F. We have shown previously [M. Prymakowska-Bosak et al. (1999) Plant Cell 11:2317-2329] that reversal of the natural proportion of major to minor H1 variants in transgenic tobacco plants results in a characteristic male-sterility phenotype identical to that occurring in many plant species subjected to water deficit at the time of male meiosis. It has been proposed by others that the drought-induced arrest of male gametophyte development is linked to decreased sugar delivery to reproductive tissues. Within the family of angiosperm H1s there is a well-defined class of minor H1 variants named "drought inducible" because some of its members have been shown to be induced by water deficit. We have identified and cloned the tobacco H1C gene, which, based on sequence similarity, represents a "drought-inducible" minor H1 variant. Analysis of the un-translated mRNA and promoter regions of H1C suggests a regulation by sucrose concentration. Antisense silencing of H1C and its close homologue H1D in plants that do not express H1A and H1B does not affect the characteristic H1A(-)/ H1B(-) male-sterility phenotype. Silencing of H1C and H1D also has no effect on growth and development of plants. Our findings demonstrate that H1C and H1D are dispensable for normal growth and development of tobacco, and that the compensatory up-regulation of "drought-inducible" H1s observed in H1A(-)/ H1B(-) plants is not the direct cause of male sterility linked to alterations in H1 variants.     

Manifestation and inheritance of <Emphasis Type="Italic">tpd1</Emphasis> phenotype in the tobacco insertion mutant with extended flowering period

The tpd1 (from tobacco pollen development 1) insertion mutant of tobacco (Nicotiana tabacum L., cv. Samsun) with extended flowering period was investigated in detail in the course of plant development, and the inheritance of the mutant phenotype was established. The wild-type and mutant plants did not differ in basic developmental indices until the floral transition; later they diverged in the characteristics of male reproductive organs, particularly in anther development and pollen maturation. The pollen of tpd1 plants was underdeveloped and sterile, resulting in a characteristic seedless phenotype with extended flowering period. When mutant flowers were pollinated with wild-type pollen, the tpd1 phenotype was maintained in at least two seed generations, indicating that this trait was heritable. The tpd1 phenotype was closely linked with kanamycin resistance; it follows that the developmental anomalies observed in our experiments immediately depended on the vector DNA insert. Our data presume that tpd1 is a rare dominant monogenic mutation with a narrowly directed physiological manifestation. A model is presented to describe the effect of TPD1. The tpd1 mutant would help identify and clone the new TPD1 gene crucial for viable pollen development.     

Endogenous cytokinin levels and metabolism of zeatin riboside in genetic tumour tissues and non-tumourous tissues of tobacco

The cytokinin content of stem tissues, primary genetic tumours (excised from 2-month-old plants) and 3-week-old in vitro cultured genetic tumour tissues derived from Nicotiana glauca (Grah.) × langsdorffii (Weinm.) and N. suaveolens (Lehm.) × langsdorffii (Weinm.) hybrids and stem tissues derived from 2-month-old N. suaveolens and N. langsdorffii plants has been analysed by radioimmunoassay. Stem tissues of tumour-prone hybrids contain high cytokinin levels (3–3.7 nmol g⁻¹). This increase is caused mainly by increased levels of cytokinin nucleotides, particularly those of zeatin nucleotide (0.5 nmol g⁻¹) in stem tissues of parent plants and 2.4 nmol g⁻¹ in stem tissues of hybrids). All other tissues contain lower cytokinin levels (0.7–1.7 nmol g⁻¹). Cytokinin bases and ribosides are major compounds in cultured tumour tissues while the nucleotides are dominant cytokinins in all freshly excised tissues from parent plants and their hybrids. In a separate study, the metabolic fate of supplied [³Hj-zeatin riboside. which is inactivated mainly by sidechain cleavage, has been studied. The results collectively suggest that cytokinins may be involved in tumourigenesis.     

Tissue-Specific Variation in the Cytokinin Habituation of Cultured Tobacco Cells

Cells of tobacco pith parenchyma sometimes lose their requirement for an exogenous supply of a cell division factor usually supplied as the synthetic cytokinin, kinetin. This change in phenotype, known as cytokinin habituation, is inherited by individual cells and appears to result from epigenetic changes rather than from rare, random, genetic mutations. We have found that tissues from different regions of the tobacco plant exhibit different states of habituation in culture. Pith tissues, as reported earlier, are usually cytokinin requiring and rapidly shift to the habituated state in culture. Leaf tissues are very slightly habituated and require kinetin for optimal rates of growth. Tissues from the stem-cortex are initially habituated. Both the leaf and cortex phenotypes are inherited by individual cells and persist for many cell generations in culture. These results show that certain tissue-specific phenotypes persist in culture and provide evidence that a process akin to habituation leading to different stable states of cytokinin requirement occurs in normal development.     

Evidence for in vitro induced mutation which improves somatic embryogenesis in Asparagus officinalis L.

Summary Somatic embryogenesis from different genotypes of Asparagus officinalis L. could be obtained by in vitro culture of shoot apices. Apices were first cultured on an auxin-rich inducing medium and then transferred onto a hormone-free development medium. All genotypes tested in this way produced a few somatic embryos. In some experiments, during the development phase, a new kind of friable highly embryogenic tissue appeared in a random manner. These tissues could be continuously subcultured on a hormone-free medium and were named embryogenic lines. Five of these embryogenic lines regenerated plants from somatic embryos. These regenerated plants exhibited an increased embryogenic response compared to the parent plants; e.g. apex culture produced somatic embryos without any auxin treatments. For one of the embryogenic lines, a genetic analysis showed that the improved embryogenic response of regenerated plants was controlled by a mendelian dominant monogenic mutation.Abbreviations LSEA low somatic embryogenesis ability - HSEA high somatic embryogenesis ability - NAA 1-naphthaleneacetic acid     

A Role for Cytokinins in De-Etiolation in Arabidopsis (det Mutants Have an Altered Response to Cytokinins)

When grown in the absence of light, Arabidopsis thaliana deetiolated (det) mutants develop many of the characteristics of light-grown plants, including the development of leaves and chloroplasts, the inhibition of hypocotyl growth elongation, and elevated expression levels of light-regulated genes. We show here that dark-grown wild-type seedlings exhibit similar phenotypic traits if any one of a variety of cytokinins are present in the growth medium. We further show that the striking phenotype of det mutants is unlikely to be caused by different levels of cytokinins in these mutants. The three major Arabidopsis cytokinins, zeatin, zeatin riboside, and isopentenyladenosine, accumulate to similar levels in wild-type seedlings grown in either the light or the dark. There is no consistently different pattern for the levels of these cytokinins in wild-type versus det1 or det2 mutants. However, det1 and det2 have an altered response to cytokinin in a detached leaf senescence assay and in tissue culture experiments. A model is proposed in which light and cytokinins act independently or sequentially through common signal transduction intermediates such as DET1 and DET2 to control the downstream light-regulated responses.     

Overexpression of Arabidopsis thaliana farnesyl diphosphate synthase (FPS1S) in transgenic Arabidopsis induces a cell death/senescence-like response and reduced cytokinin levels

To investigate the contribution of farnesyl diphosphate synthase (FPS) to the overall control of the mevalonic acid pathway in plants, we have generated transgenic Arabidopsis thaliana overexpressing the Arabidopsis FPS1S isoform. Despite high levels of FPS activity in transgenic plants (8- to 12-fold as compared to wild-type plants), the content of sterols and the levels of 3-hydroxy-3-methylglutaryl-CoA reductase activity in leaves were similar to those in control plants. Plants overexpressing FPS1S showed a cell death/senescence-like phenotype and grew less vigorously than wild-type plants. The onset and the severity of these phenotypes directly correlated with the levels of FPS activity. In leaves of plants with increased FPS activity, the expression of the senescence activated gene SAG12 was prematurely induced. Transgenic plants grown in the presence of either mevalonic acid (MVA) or the cytokinin 2-isopentenyladenine (2-iP) recovered the wild-type phenotype. Quantification of endogenous cytokinins demonstrated that FPS1S overexpression specifically reduces the levels of endogenous zeatin-type cytokinins in leaves. Altogether these results support the notion that increasing FPS activity without a concomitant increase of MVA production leads to a reduction of IPP and DMAPP available for cytokinin biosynthesis. The reduced cytokinin levels would be, at least in part, responsible for the phenotypic alterations observed in the transgenic plants. The finding that wild-type and transgenic plants accumulated similar increased amounts of sterols when grown in the presence of exogenous MVA suggests that FPS1S is not limiting for sterol biosynthesis.     

Cold-sensitive expression of cytokinin habituation by tobacco pith cells in culture

Cloned, cytokinin-habituated tissues of Nicotiana tobacum L. cv. Havana 425 are able to grow in culture at 25° C without added cytokinin. These tissues vary in their expression of the habituated phenotype at 16° C. When cytokinin-requiring pith tissues are converted to the habituated state by 35° C treatment, all of the habituated cells are cold sensitive. After several transfers in culture, some of these habituated cells give rise to stable, cold resistant variants. Both phenotypes are inherited by individual cells. Cold sensitive clones at 16° C and non-habituated clones at 16° C as well as 25° C show the same dose response to the cytokinin, kinetin. This suggests that at the physiological level, cold sensitivity results from a decreased production of cell division factors rather than from a decreased affinity of cellular receptors for these factors.Abbreviations CDF Cell division factor(s) - NAA -naphthalencacetic acid     

Protocols for efficient repetitive and secondary somatic embryogenesis in Helianthus maximiliani (Schrader)

 Indirect somatic embryogenesis was induced on leaf explants of greenhouse-grown Helianthus maximiliani plants. Leaves of the regenerated plants were used as starting explants for the induction of direct somatic embryogenesis. Another cycle of somatic embryogenesis was induced on the leaves of regenerated plants. In both cases, leaf explants were cultured on media containing different auxin/cytokinin ratios. The auxin/cytokinin ratio had an influence on the intensity of embryo formation, germination and the capability to regenerate plants. Somatic embryogenesis was generally more intensive on the medium with lower concentrations of 6-benzylamino-purine. Further, the percentage of regenerated plants was higher when embryos were induced on high-cytokinin, low-auxin medium. Secondary somatic embryogenesis was induced on embryos by culture in liquid hormone-free medium. Similar to direct embryogenesis the efficiency of secondary embryogenesis depended on the medium used for the induction of the primary embryos. In contrast to the mostly low frequencies of conversion of secondary embryos into plants that has been observed in other species, the percentage of regenerated plants from secondary embryos of H. maximiliani was quite high, although slightly lower than that obtained in primary embryos. Received: 28 March 2000 / Revision received: 1 September 2000 / Accepted: 2 October 2000     

Highly Branched Phenotype of the Petunia dad1-1 Mutant Is Reversed by Grafting

The recessive dad1-1 allele conditions a highly branched growth habit resulting from a proliferation of first- and second-order branches. Unlike the wild-type parent, which has lateral branching delayed until the third or fourth leaf node distal to the cotyledons, dad1-1 initiates lateral branching from each cotyledon axil. In addition to initiating lateral branching sooner than the wild type, dad1-1 sustains branching through more nodes on the main shoot axis than the wild type. In keeping with a propensity for branching at basal nodes, dad1-1 produces second-order branches at the proximal-most nodes on first-order branches and small shoots from accessory buds at basal nodes on the main shoot axis. Additional traits associated with the mutation are late flowering, adventitious root formation, shortened internodes, and mild leaf chlorosis. Graft studies show that a dad1-1 scion, when grafted onto wild-type stock, is converted to a phenotype resembling the wild type. Furthermore, a small wild-type interstock fragment inserted between a mutant root stock and a mutant scion is sufficient to convert the dad1-1 scion from mutant to a near wild-type appearance. The recessive dad1-1 phenotype combines traits associated with cytokinin overexpression, auxin overexpression, and gibberellin limitation, which suggests a complex interaction of hormones in establishing the mutant phenotype.