Production of transgenic sugarcane (Saccharum officinarum L.) plants by intact cell electroporation

Summary We describe an efficient procedure for genetic transformation of commercial sugarcane varieties POJ 2878 and Ja 60-5. The transformation protocol is based on electroporation of a plasmid conferring GUS activity into cell clusters isolated from embryogenic calli. Six to eight weeks after electroporation, Ja 60-5 plants regenerated from electroporated tissues were tested and confirmed to be transgenic using histochemical glucuronidase and Southern hybridization analysis. Electroporation of intact cells is an efficient and reproducible method for sugarcane transformation and may also be useful for transformation of other plants.Abhrevations GUS -glucuronidase - CAT chloramphenicol acetyl transferase - PCV packed cell volume - PCR polymerase chain reaction - DTT dithiotreitol - Hepes N-2-Hydroxyethylpiperazine-N'-2-ethanesulfonic acid - 2,4-D 2,4-dichlorophenoxyacetic acid - NOS nopaline synthase - 4-MUG 4-methylumbelliferyl -D-glucuronide     

Complete nucleotide sequence of the sugarcane (Saccharum officinarum) chloroplast genome: a comparative analysis of four monocot chloroplast genomes.

The complete nucleotide sequence of the chloroplast genome of sugarcane (Saccharum officinarum) has been determined. It is a circular double-stranded DNA molecule, 141,182 bp in size, and is composed of a large single copy of 83,048 bp, a small single copy of 12,544 bp, and a pair of inverted repeat regions of 22,795 bp each. A comparative analysis among monocots showed that the sugarcane chloroplast genome was very similar to maize but not to rice or wheat. Between sugarcane and maize at the rps16-trnQ (UUG) region, however, a length polymorphism was identified. With regard to insertions/deletions equal to or longer than 5 bp, a total of 53 insertion and 31 deletion events were identified in the sugarcane chloroplast genome. Of the 84 loci identified, a pair of direct repeat sequences was located side by side in a tandem fashion in 47 loci (56.0%). A recombination event during plant evolution is discussed at two sites between the sugarcane and tobacco chloroplast genomes.     

Establishment of embryogenic callus and high protoplast yielding suspension cultures of sugarcane (Saccharum spp. hybrids)

For 18 sugarcane cultivars, four distinct callus types developed on leaf explant tissue cultured on modified MS medium, but only Type 3 (embryogenic) and Type 4 (organogenic) were capable of plant regeneration. Cell suspension cultures were initiated from embryogenic callus incubated in a liquid medium. In stage one the callus adapted to the liquid medium. In stage two a heterogeneous cell suspension culture formed in 14 cultivars after five to eight weeks of culture. In stage three a homogeneous cell suspension culture was developed in six cultivars after 10 to 14 weeks by selective subculturing to increase the proportion of actively dividing cells from the heterogeneous cell suspension culture. Plants were regenerated from cell aggregates in heterogeneous cell suspension cultures for up to 148 days of culture but plants could not be regenerated from homogeneous cell suspension cultures. High yields of protoplasts were obtained from homogeneous cell suspension cultures (3.4 to 5.2 × 10⁶ protoplasts per gram fresh weight of cells [gfwt^-1]) compared to heterogeneous cell suspension cultures (0.1 × 10⁶ protoplasts gfwt^-1). Higher yields of protoplasts were obtained from homogeneous cell suspension cultures for cultivars Q63 and Q96 after regenerating callus from the cell suspension cultures, then recycling this callus to liquid medium (S-cell suspension cultures). This process increased protoplast yield to 9.4 × 10⁶ protoplasts gfwt^-1. Protoplasts isolated from S-cell suspension cultures were regenerated to callus and recycled to produce SP-cell suspension cultures yielding 6.4 to 13.2 × 10⁶ protoplasts gfwt^-1. This recycling of callus to produce S-cell suspension cultures allowed protoplasts to be isolated for the first time from cell lines of cultivars Q110 and Q138.     

Sugarcane biotechnology: The challenges and opportunities

Summary Commercial sugarcane, belonging to the genus Saccharum (Poaceae), is an important industrial crop accounting for nearly 70% of sugar produced worldwide. Compared to other major crops, efforts to improve sugarcane are limited and relatively recent, with the first introduction of interspecific hybrids about 80 yr ago. Progress in traditional breeding of sugareane, a highly polyploid and frequently aneuploid plant, is impeded by its narrow gene pool, complex genome, poor fertility, and the long breeding/selection cycle. These constraints, however, make sugarcane a good candidate for molecular breeding. In the past decade considerable progress has been made in understanding and manipulating the sugarcane genome using various biotechnological and cell biological approaches. Notable among them are the creation of transgenic plants with improved agronomic or other important traits, advances in genomics and molecular markers, and progress in understanding the molecular aspects of sucrose transport and accumulation. More recently, substantial effort has been directed towards developing sugarcane as a biofactory for high-value products. While these achievements are commendable, a greater understanding of the sugarcane genome, and cell and whole plant physiology, will accelerate the implementation of commercially significant biotechnology outcomes. We anticipate that the rapid advancements in molecular biology and emerging biotechnology innovations would play a significant role in the future sugarcane crop improvement programs and offer many new opportunities to develop it as a new-generation industrial crop.     

Biostimulation of micro-organisms from sugarcane bagasse pith for the removal of weathered hydrocarbon from soil

AIMS: In this study we studied the biostimulation of micro-organisms associated with sugarcane bagasse pith for the removal of total petroleum hydrocarbon from a soil contaminated with weathered hydrocarbon. METHODS AND RESULTS: Carbon, nitrogen and phosphorus were added at a ratio of 100 : 10 : 1, water content of 40%, and soil : bagasse ratio of 49 : 1. A significant positive difference (P < 0.05) was observed in total petroleum hydrocarbon removal (38 and 48%) by micro-organisms associated with bagasse and native soil micro-organisms, respectively. In addition, total petroleum hydrocarbon removal increased to 60% in a system where both autochthonous soil and bagasse micro-organisms were present. CONCLUSIONS: Micro-organisms from sugarcane bagasse pith can be stimulated for removal of weathered hydrocarbon from contaminated tropical soils, without they being inhibited by indigenous soil micro-organisms. SIGNIFICANCE AND IMPACT OF THE STUDY: Soil of with hydrocarbons can be diminished by stimulation of autochthonous microflora present in soil and agricultural residues. This work contributes to the microbiology of composting, as low amounts of bulking agents for hydrocarbon removal from soil, can be used.     

Isolation and characterization of <Emphasis Type="Italic">Azotobacter</Emphasis> and <Emphasis Type="Italic">Azospirillum</Emphasis> strains from the sugarcane rhizosphere

Bacteria with the ability to grow on nitrogen-free media and with nitrogenase activity under aerobic or microaerobic conditions were isolated from sugarcane roots collected from four different agricultural locations in Granada (Spain). Isolates were Gram negative rods and were identified as Azotobacter chroococcum and Azospirillum brasilense. Our results suggest that Azotobacter isolates do not have a particular affinity for sugarcane rhizospheres and that, on the contrary, Azospirillum isolates show specific association and perhaps endophytic colonization of sugarcane. However, obligate endophytes (Gluconacetobacter diazotrophicus) were not found in the apoplastic fluid of the stems and macerates extracts of sugarcane tissues with the procedure applied. Population of this microorganism might be in low number in the Spanish sugarcane varieties studied which is also discussed.     

Production of biologically active GM-CSF in sugarcane: a secure biofactory

Over 300 transgenic sugarcane plants representing approx. 200 independent lines producing the human cytokine granulocyte macrophage colony stimulating factor (GM-CSF) were analyzed for recombinant protein accumulation and activity levels. Expression constructs differed in use of the maize polyubiquitin 1, Mubi-1, or the sugarcane polyubiquitin 9, SCubi9, promoters; presence or absence of a C-terminal HDEL tag for ER retention; and presence or absence of a 6X Histidine tag for metal ion affinity purification. Accumulation of GM-CSF protein ranged from undetectable to 0.02 of total soluble protein. No significant difference was observed between the two promoters; however, the ER retention tag was required for higher accumulation levels. Human bone marrow cells (TF-1), which require GM-CSF for cell division, proliferated when growth media was supplemented with transgenic sugarcane extracts. Comparison to purified commercially produced GM-CSF indicated the sugarcane-produced protein had essentially identical activity levels. In a 14-month field trial, accumulation levels remained stable. This is the first report of field production of GM-CSF. During the field trial, no flowering of the trial plants occurred; no pollen or seed was produced. Drying, burning, and burial of the test plants effectively blocked possible routes for the transgenic sugarcane to enter the environment or food supply. Sugarcane may provide a highly secure system for biofactory production of pharmaceutical proteins.This revised version was published online in May 2005 with corrections to the last authors name.     

Molasses melanoidin-like products enhance phytoextraction of lead through three Brassica species

Previously, it has been suggested that melanoidin-like products (MLP) from sugarcane molasses may accelerate copper phytoextraction. In this study, we evaluated the facilitatory effect of MLP on phytoextraction in a medium including cadmium or lead, the concentrations of which were adjusted around the regulation values of the Soil Contamination Countermeasures Act in Japan. Three Brassica species were tested based on their fast growth, high biomass productivity, and high heavy metal absorption. Both biomass and lead uptake in the nutrient medium with 1 mM lead nitrate were significantly increased by the addition of MLP, and almost all of the lead was accumulated in the root tissue. Therefore, MLP were able both to detoxify lead ions and to improve their bioavailability in Brassica species. In contrast, only these species with MLP or citric acid survived in the nutrient medium with 1 mM cadmium sulfate. The phytoextraction of cadmium using these species was therefore impractical under the Act.     

Comparative evaluation of acid and alkaline sulfite pretreatments for enzymatic saccharification of bagasses from three different sugarcane hybrids

Sugarcane bagasses from three experimental sugarcane hybrids and a mill‐reference sample were used to compare the efficiency and mode of action of acid and alkaline sulfite pretreatment processes. Varied chemical loads and reaction temperatures were used to prepare samples with distinguished characteristics regarding xylan and lignin removals, as well as sulfonation levels of residual lignins. The pretreatment with low sulfite loads (5%) under acidic conditions (pH 2) provided maximum glucose yield of 70% during enzymatic hydrolysis with cellulases (10 FPU/g) and β‐glucosidases (20 UI/g bagasse). In this case, glucan enzymatic conversion from pretreated materials was mostly associated with extensive xylan removal (70–100%) and partial delignification occurred during the pretreatment. The use of low sulfite loads under acidic conditions required pretreatment temperatures of 160°C. In contrast, at a lower pretreatment temperature (120°C), alkaline sulfite process achieved similar glucan digestibility, but required a higher sulfite load (7.5%). Residual xylans from acid pretreated materials were almost completely hydrolysed by commercial enzymes, contrasting with relatively lower xylan to xylose conversions observed in alkaline pretreated samples. Efficient xylan removal during acid sulfite pretreatment and during enzymatic digestion can be useful to enhance glucan accessibility and digestibility by cellulases. Alkaline sulfite process also provided substrates with high glucan digestibility, mainly associated with delignification and sulfonation of residual lignins. The results demonstrate that temperature, pH, and sulfite can be combined for reducing lignocellulose recalcitrance and achieve similar glucan conversion rates in the alkaline and acid sulfite pretreated bagasses. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 34:944–951, 2018     

Transgenic sugarcane plants resistant to stem borer attack

A truncated cryIA(b) gene encoding the active region of the Bacillus thuringiensis -endotoxin was expressed in transgenic sugarcane plants (Saccharum officinarum L.) under the control of the CaMV 35S promoter. Genetic transformation was accomplished by electroporation of intact cells. The levels of recombinant toxin were established and biological activity tests were performed against neonate sugarcane borer (Diatraea saccharalis F.) larvae. Transgenic sugarcane plants showed significant larvicidal activity despite the low expression of CryIA(b).