Targeted modification of storage protein content resulting in improved amino acid composition of barley grain.

C-hordein in barley and ω-gliadins in wheat are members of the prolamins protein families. Prolamins are the major component of cereal storage proteins and composed of non-essential amino acids (AA) such as proline and glutamine therefore have low nutritional value. Using double stranded RNAi silencing technology directed towards C-hordein we obtained transgenic barley lines with up to 94.7% reduction in the levels of C-hordein protein relative to the parental line. The composition of the prolamin fraction of the barley parental line cv. Golden Promise was resolved using SDS-PAGE electrophoresis, the protein band were excised and the proteins identified by quadrupole-time-of-flight mass spectrometry. Subsequent SDS-PAGE separation and analysis of the prolamin fraction of the transgenic lines revealed a reduction in the amounts of C-hordeins and increases in the content of other hordein family members. Analysis of the AA composition of the transgenic lines showed that the level of essential amino acids increased with a concomitant reduction in proline and glutamine. Both the barley C-hordein and wheat ω-gliadin genes proved successful for RNAi-gene mediated suppression of barley C-hordein level. All transgenic lines that exhibited a reduction for C-hordein showed off-target effects: the lines exhibited increased level of B/γ-hordein while D-hordein level was reduced. Furthermore, the multicopy insertions correlated negatively with silencing.

Leaf senescence and nutrient remobilisation in barley and wheat.

Extensive studies have been undertaken on senescence processes in barley and wheat and their importance for the nitrogen use efficiency of these crop plants. During the senescence processes, proteins are degraded and nutrients are re-mobilised from senescing leaves to other organs, especially the developing grain. Most of the proteins degraded reside in the chloroplasts, with Rubisco constituting the most dominant protein fraction. Despite intensive studies, the proteases responsible for Rubisco degradation have not yet been identified. Evidence for degradation of stromal proteins outside of chloroplasts is summarised. Rubisco is thought to be released from chloroplasts into vesicles containing stroma material (RCB = Rubisco-containing bodies). These vesicles may then take different routes for their degradation. Transcriptome analyses on barley and wheat senescence have identified genes involved in degradative, metabolic and regulatory processes that could be used in future strategies aimed at modifying the senescence process. The breeding of crops for characters related to senescence processes, e.g. higher yields and better nutrient use efficiency, is complex. Such breeding has to cope with the dilemma that delayed senescence, which could lead to higher yields, is correlated with a decrease in nutrient use efficiency. Pinpointing regulatory genes involved in senescence might lead to tools that could effectively overcome this dilemma.

Transformation of barley by microinjection into isolated zygote protoplasts.

Barley zygote protoplasts were mechanically isolated, embedded in agarose droplets, and microinjected with a rice actin promoter Act1-gusA-nos gene construct. On average 62% of the cells survived the injection and of these 55% continued development into embryo-like structures and eventually to plants. PCR screening for the presence of a 307-bp fragment in the middle of the gusA gene showed that on average 21% of the derived structures contained this fragment. However, among the hundreds of injected zygotes, derived structures and regenerants we only found significant GUS expression in two cases (embryo-like structures nine days after injection). Two lines of green plants, derived from zygotes microinjected with linearized plasmid (line A147-1) or an isolated Act1-gusA-nos gene cassette (line A166-h) proved to be transgenic. Line A147-1 appeared to contain a single and intact copy of the expression cassette but a PCR based progeny analysis indicated the presence of additional shorter fragments of the cassette. Line A166-h appeared to contain a single fragment of the gusA gene that was transferred to the progeny as a single Mendelian trait. One additional fragment of the gusA gene was identified in this line. The present data show that transformation of barley by microinjection of DNA into isolated zygotes is feasible but also that gene expression rarely is achieved, possibly due to degradation of the introduced DNA.

Engineering of the aspartate family biosynthetic pathway in barley (Hordeum vulgare L.) by transformation with heterologous genes encoding feed-back-insensitive aspartate kinase and dihydrodipicolinate synthase.

In prokaryotes and plants the synthesis of the essential amino acids lysine and threonine is predominantly regulated by feed-back inhibition of aspartate kinase (AK) and dihydrodipicolinate synthase (DHPS). In order to modify the flux through the aspartate family pathway in barley and enhance the accumulation of the corresponding amino acids, we have generated transgenic barley plants that constitutively express mutant Escherichia coli genes encoding lysine feed-back insensitive forms of AK and DHPS. As a result, leaves of primary transformants (T0) exhibited a 14-fold increase of free lysine and an 8-fold increase in free methionine. In mature seeds of the DHPS transgenics, there was a 2-fold increase in free lysine, arginine and asparagine and a 50% reduction in free proline, while no changes were observed in the seeds of the two AK transgenic lines analysed. When compared to that of control seeds, no differences were observed in the composition of total amino acids. The introduced genes were inherited in the T1 generation where enzymic activities revealed a 2.3-fold increase of AK activity and a 4.0-9.5-fold increase for DHPS. T1 seeds of DHPS transformants showed the same changes in free amino acids as observed in T0 seeds. It is concluded that the aspartate family pathway may be genetically engineered by the introduction of genes coding for feed-back-insensitive enzymes, preferentially giving elevated levels of lysine and methionine.

Dynamics of Nuclear DNA Quantities during Zygote Development in Barley.

Quantities of DNA were estimated in the nuclei of mechanically isolated egg and zygote protoplasts in two cultivars of barley using 4[prime],6-diamidino-2-phenylindole staining and microfluorometry. Unlike many previous studies on DNA amounts within the sex cells of flowering plants, we obtained consistent and unambiguous results indicating that the egg and sperm nuclei are at the 1C DNA level (basic haploid amount) at the time of karyogamy. Karyogamy was initiated within 60 min postpollination, and the male chromatin became completely integrated into the egg nucleus within 6 to 7 hr postpollination (hpp). Zygotic nuclear DNA levels began to increase at ~9 to 12 hpp in cultivar Alexis and at 12 to 15 hpp in cultivar Igri. The 4C DNA complement was reached in most zygotes by 22 to 26 hpp in cultivar Alexis and by 23 to 29 hpp in cultivar Igri. These data are fundamental to a better understanding of fertilization and zygote maturation in flowering plants. They are also relevant to studies in which the timing of zygotic DNA replication is of interest, such as ongoing investigations on genetic transformations in barley using the microinjection technique.

Regeneration of Fertile Barley Plants from Mechanically Isolated Protoplasts of the Fertilized Egg Cell.

A simple procedure is described for the mechanical isolation of protoplasts of unfertilized and fertilized barley egg cells from dissected ovules. Viable protoplasts were isolated from ~75% of the dissected ovules. Unfertilized protoplasts did not divide, whereas almost all fertilized protoplasts developed into microcalli. These degenerated when grown in medium only. When cocultivated with barley microspores undergoing microspore embryogenesis, the protoplasts of the fertilized egg cells developed into embryo-like structures that gave rise to fully fertile plants. On average, 75% of cocultivated protoplasts of fertilized egg cells developed into embryo-like structures. Fully fertile plants were regenerated from ~50% of the embryo-like structures. The isolation-regeneration techniques may be largely genotype independent, because similar frequencies were obtained in two different barley varieties with very different performance in anther and microspore culture. Protoplasts of unfertilized and fertilized eggs of wheat were isolated by the same procedure, and a fully fertile wheat plant was regenerated by cocultivation with barley microspores.

Ultrastructural analysis of meiotic recombination and chiasma formation.

Meiotic recombination appears to be mediated by recombination nodules, small electron dense spheres, associated with the central region of the synaptonemal complex. These structures are a prerequisite for, not the result of crossing over and they undergo complex structural, numerical and distributional changes before the final distribution of crossovers is achieved. In the organisms studied the nodules are placed randomly along and among the bivalents at zygotene. Subsequently, the distribution is modified to insure that each bivalent and generally each bivalent arm attain a nodule and that close spacing of nodules is minimized. Analysis of the number and location of recombination nodules at pachytene provides knowledge of the number and physical distribution of crossovers in the individual bivalents. Chiasmata originate from recombination nodules. At early diplotene the chiasma consists of a retained segment of synaptonemal complex containing a derivative of a recombination nodule. At late meiotic prophase the segment is eliminated after the formation of a chromatin chiasma.

The synaptonemal complex, recombination nodules and chiasmata in human spermatocytes.

Reconstruction from serial sections of 120 human spermatocyte nuclei, ranging in stage from leptotene to anaphase I, has led to the following conclusions. The reconstructed nuclei form a continuous sequence of developmental stages. With few exceptions, all of the bivalents are identifiable by length, centromere index and morphological markers. Crossing over is accompanied by a transformation of the recombination nodule (RN) into a fusiform bar lying across the synaptonemal complex (SC). The evolution of the crossover distribution at late pachytene is regulated at two levels both involving the SC. Each bivalent displays a pattern of SC regions - domains - with high affinity for RNs in the middle and low affinity at the ends. The occurrence of crossing over in a domain reduces the probability of attachment of new RNs and causes RNs not yet involved in crossing over to be released from that domain. Positive interference between crossovers is a consequence of these phenomena. At diplotene the degradation of the SC is initiated in regions with low affinity for RNs and small segments of the SC are retained at the crossover sites until late diakinesis. The site of crossing over is only identifiable by an RN for a certain period of time during pachytene. The distribution of total crossovers in a nucleus is similar but not identical to the distribution of chiasmata as seen in the light microscope. The number of crossovers has been estimated to be 70 and exceeds the number of chiasmata determined by light microscopy by a factor of 1.4.

Ultrastructural characterization of the meiotic prophase. A tool in the assessment of radiation damage in man.

The three-dimensional reconstruction of meiotic nuclei from serial sections micrographed in the electron microscope has provided information about man and several other organisms that is not obtainable by light microscopy or biochemical analysis. At zygotene, the previously unpaired chromosomes align and form synaptonemal complexes between homologous chromosome segments either by progressive initiation from the telomeres or by interstitial recognition. Chromosome and bivalent interlocking at zygotene is a regular phenomenon and occurs at a frequency of 0.7-4.0 per nucleus in samples of meiocytes analyzed from different organisms. This frequency is reduced to 0.1 per nucleus at pachytene. The interlockings are resolved by breakage and precise rejoining of the broken ends. This breakage and rejoining can also occur in the absence of the DNA nicking and repair involved in crossing-over. The synaptonemal complexes combining homologous chromosome segments are stabilized by recombination nodules, after which a second round of synaptonemal complex formation between as yet unpaired or unstably paired chromosome segments occurs, apparently for optimization of bivalent formation. Non-homologous pairing with the synaptonemal complex can take place in this phase of pachytene. Continuity between recombination nodules and chromatin chiasmata has been traced at the ultrastructural level but not all nodules lead to chiasmata. The distributions of recombination nodules among the bivalents and along the bivalents at successive stages of meiotic prophase show that the nodules are placed at random at early-zygotene after which bivalents without nodules have preference for the acquisition of these structures. Chiasma interference appears as a consequence of the limited number of recombination nodules available together with a decreased affinity of a bivalent arm with a nodule for additional ones. The relevance of these observations in the study of genetic damage by radiation is discussed.