Rick E. Masonbrink

Synthetic Chromosome Platforms in Plants

Synthetic chromosomes provide the means to stack transgenes independently of the remainder of the genome. Combining them with haploid breeding could provide the means to transfer many transgenes more easily among varieties of the same species. The epigenetic nature of centromere formation complicates the production of synthetic chromosomes. However, telomere-mediated truncation coupled with the introduction of site-specific recombination cassettes has been used to produce minichromosomes consisting of little more than a centromere. Methods that have been developed to modify genes in vivo could be applied to minichromosomes to improve their utility and to continue to increase their length and genic content. Synthetic chromosomes establish the means to add or subtract multiple transgenes, multigene complexes, or whole biochemical pathways to plants to change their properties for agricultural applications or to use plants as factories for the production of foreign proteins or metabolites.

Engineered Minichromosomes in Plants

Engineered minichromosomes provide the ability to target transgenes to a defined insertion position for predictable expression on an independent chromosome. This technology promises to provide a means to add many genes to a synthetic chromosome in sequential manner. An additional advantage is that the multiple transgenes will not be inserted into the normal chromosomes and thus will not exhibit linkage drag when converging the transgenes to different germplasm nor will they be mutagenic. Telomere truncation coupled with the introduction of site-specific recombination cassettes has proven to be an easy method to produce minichromosomes. Telomere truncation results from the transformation of plasmids carrying a block of telomere repeats at one end. Minichromosomes consisting of little more than a centromere have been produced for B chromosomes of maize. Such small chromosomes have been studied for their meiotic behavior, which differs from normal sized chromosomes in that homologue pairing is rare or nonexistent and sister chromatid cohesion fails at meiosis I. Potential modifications of the minichromosomes that can address these issues are discussed. Minichromosomes can be recovered from transformed plants that are polyploid or that carry an additional chromosome as the preferred target for truncation. Site-specific recombination has been demonstrated to operate on these terminally located sites. By introducing normal B chromosomes into lines with engineered mini-B chromosomes, the latter can be increased in copy number, which provides the potential to augment the expression of the introduced genes. Because the vast majority of plant species have the same telomere sequence, the truncating transgenes should be effective in most plants to generate engineered minichromosomes. Such chromosomes establish the means to add or subtract multiple transgenes, multigene complexes, or whole biochemical pathways to plants to change their properties for agronomic applications or to use plants as factories for the production of foreign proteins or metabolites.

In vivo modification of a maize engineered minichromosome

Engineered minichromosomes provide efficient platforms for stacking transgenes in crop plants. Methods for modifying these chromosomes in vivo are essential for the development of customizable systems for the removal of selection genes or other sequences and for the addition of new genes. Previous studies have demonstrated that Cre, a site-specific recombinase, could be used to modify lox sites on transgenes on maize minichromosomes; however, these studies demonstrated somatic recombination only, and modified minichromosomes could not be recovered. We describe the recovery of an engineered chromosome composed of little more than a centromere plus transgene that was derived by telomere-mediated truncation. We used the fiber fluorescence in situ hybridization technique and detected a transgene on the minichromosome inserted among stretches of CentC centromere repeats, and this insertion was large enough to suggest a tandem insertion. By crossing the minichromosome to a plant expressing Cre-recombinase, the Bar selection gene was removed, leaving behind a single loxP site. This study demonstrates that engineered chromosomes can be modified in vivo using site-specific recombinases, a demonstration essential to the development of amendable chromosome platforms in plants.

Multiple maize minichromosomes in meiosis

In this study, four distinct minichromosomes derived from the maize B chromosome, were increased in copy number using the B chromosomes accumulation mechanism, namely nondisjunction at the second pollen mitosis and preferential fertilization of the egg. These minichromosomes provide the unique opportunity to examine the behavior of many copies of a single chromosome in an otherwise diploid background. While multiple copies were associated in multivalent configurations, they often dissociated into univalents or bivalents prior to metaphase I. The largest minis behavior closely resembled the progenitor B chromosome, but all smaller chromosomes showed failure of sister chromatid cohesion. In addition to the meiotic behavior, we observed many anomalies of univalent behavior and possible heterochromatic fusions of B repeat associated heterochromatin.

Recovery of a telomere-truncated chromosome via a compensating translocation in maize

Maize-engineered minichromosomes are easily recovered from telomere-truncated B chromosomes but are rarely recovered from A chromosomes. B chromosomes lack known genes, and their truncation products are tolerated and transmitted during meiosis. In contrast, deficiency gametes resulting from truncated A chromosomes prevent their transmission. We report here a de novo compensating translocation that permitted recovery of a large truncation of chromosome 1 in maize. The truncation (trunc-1) and translocation with chromosome 6 (super-6) occurred during telomere-mediated truncation experiments and were characterized using single-gene fluorescent in situ hybridization (FISH) probes. The truncation contained a transgene signal near the end of the broken chromosome and transmitted together with the compensating translocation as a heterozygote to approximately 41%-55% of progeny. Transmission as an addition chromosome occurred in ~15% of progeny. Neither chromosome transmitted through pollen. Transgene expression (Bar) cosegregated with trunc-1 transcriptionally and phenotypically. Meiosis in T1 plants revealed eight bivalents and one tetravalent chain composed of chromosome 1, trunc-1, chromosome 6, and super-6 in diplotene and diakinesis. Our data suggest that de novo compensating translocations allow recovery of truncated A chromosomes by compensating deficiency in female gametes and by affecting chromosome pairing and segregation. The truncated chromosome can be maintained as an extra chromosome or together with the super-6 as a heterozygote.

Sporophytic nondisjunction of the maize B chromosome at high copy numbers.

It has been known for decades that the maize B chromosome undergoes nondisjunction at the second pollen mitosis. Fluorescence in-situ hybridization (FISH) was used to undertake a quantitative study of maize plants with differing numbers of B chromosomes to observe if instability increases by increasing B dosage in root tip tissue. B chromosome nondisjunction was basically absent at low copy number, but increased at higher B numbers. Thus, B nondisjunction rates are dependent on the dosage of Bs in the sporophyte. Differences in nondisjunction were also documented between odd and even doses of the B. In plants that have inherited odd numbered doses of the B chromosome, B loss is nearly twice as likely as B gain in a somatic division. When comparing plants with even doses of Bs to plants with odd doses of Bs, plants with even numbers had a significantly higher chance to increase in number. Therefore, the Bs non-disjunctive capacity, previously thought to be primarily restricted to the gametophyte, is present in sporophytic cells.

Accumulation of multiple copies of maize minichromosomes.

Multiple copies of B chromosomes in maize (Zea mays) can accumulate in the genome using the B chromosome’s accumulation mechanism, specifically nondisjunction at the second pollen mitosis and preferential fertilization of the egg. Using this mechanism, we accumulated 4 different-sized minichromosomes derived from the B chromosome to test the chromosome limits of the cell. The accumulation of normal B chromosomes is associated with multiple phenotypes including white stripes and asymmetric leaf blades, but when minichromosomes are accumulated these symptoms are absent. We also found that multiple B chromosome-derived minichromosomes can coexist with A chromosome-derived minichromosomes. During the years that these experiments were conducted, we found many B chromosome rearrangements and fragments, 2 recoverable A chromosome fragments, and observed a minichromosome breakage-fusion-bridge cycle in roots.

A Cluster of Recently Inserted Transposable Elements Associated with siRNAs in Gossypium raimondii

Stabilization of transposable element (TE) copy number involves the biosynthesis of short silencing RNAs (siRNAs) and further initialization of siRNA‐mediated TE silencing. To gain insight into the relationship between the biosynthesis of siRNAs and their source TEs, we examined the co‐evolutionary dynamics and expression of these two entities by characterizing the siRNA distribution across the genome of Gossypium raimondii Ulbr. We identified an unusual region at the 3’ end of chromosome 1 with significantly enriched siRNA coverage. Analysis of the correlation pattern between uniquely mapped siRNAs and those mapping to multiple regions implicated active biogenesis of siRNAs from these potential young TEs. Furthermore, divergence estimates of TEs within this region confirmed that the majority of TEs are young. Active transcription of the source TEs and their positive correlation with expressed siRNAs indicates that sufficient expression of TEs may be necessary to generate siRNAs and maintain the silenced state of recently transposed TEs.

Heritable Loss of Replication Control of a Minichromosome Derived from the B Chromosome of Maize

During an accumulation regime of a small telomere-truncated B chromosome, a derivative with large variations in size and multiple punctate centromere loci exhibiting amplified copy numbers was discovered. Multiple centromere satellite loci or transgene signals were documented in amplified chromosomes, suggesting over-replication. Immunolocalization studies revealed multiple foci of biochemical markers characteristic of active centromeres such as CENP-C and phosphorylation of histones H3S10 and H2AThr133. The amplified chromosomes exhibit an absence of chromosome disjunction in meiosis I and an infrequent chromosome disjunction in meiosis II. Despite their unusual structure and behavior these chromosomes were observed in the lineage for seven generations during the course of this study. While severely truncated relative to a normal B chromosome, the progenitor minichromosome is estimated to be at least several megabases in size. Given that the centromere and transgene signals at opposite ends of the chromosome generally match in copy number, the replication control is apparently lost over several megabases.

The genome of the soybean cyst nematode (Heterodera glycines) reveals complex patterns of duplications involved in the evolution of parasitism genes

Heterodera glycines, commonly referred to as the soybean cyst nematode (SCN), is an obligatory and sedentary plant parasite that causes over a billion-dollar yield loss to soybean production annually. Although there are genetic determinants that render soybean plants resistant to certain nematode genotypes, resistant soybean cultivars are increasingly ineffective because their multi-year usage has selected for virulent H. glycines populations. The parasitic success of H. glycines relies on the comprehensive re-engineering of an infection site into a syncytium, as well as the long-term suppression of host defense to ensure syncytial viability. At the forefront of these complex molecular interactions are effectors, the proteins secreted by H. glycines into host root tissues. The mechanisms of effector acquisition, diversification, and selection need to be understood before effective control strategies can be developed, but the lack of an annotated genome has been a major roadblock. Here, we use PacBio long-read technology to assemble a H. glycines genome of 738 contigs into 123Mb with annotations for 29,769 genes. The genome contains significant numbers of repeats (34%), tandem duplicates (18.7Mb), and horizontal gene transfer events (151 genes). Using previously published effector sequences, the newly generated H. glycines genome, and comparisons to other nematode genomes, we investigate the evolutionary mechanisms responsible for the emergence and diversification of effector genes.