星星草大、小孢子发生与雌、雄配子体发育的观察

利用常规石蜡制片法研究了星星草[Puccinellia tenutiflora(Griseb．)Scribn．et Merr．]大、小孢子发生及其雌、雄配子体的发育过程。主要结论是：(1)小孢子母细胞减数分裂过程中的胞质分裂为连续型,四分孢子为左右对称型;(2)成熟的花粉为三细胞型,具单萌发孔;(3)花药壁由4层结构组成,最外层为表皮,其内分别为药室内壁、中层、绒毡层,绒毡层为分泌型,花药壁的发育属于单子叶型;(4)星星草为单子房,单胚珠,双珠被,薄珠心,倒生型胚珠。大孢子母细胞经减数分裂形成线形排列的4个大孢子,合点端大孢子具功能;(5)胚囊发育属于蓼型,成熟胚囊形成时,反足细胞经无丝分裂形成4～6个反足细胞,反足细胞内可能存在多次DNA复制过程。     

Microtubule organization in cultured soybean and black spruce cells: Interphase —mitosis transition and spindle morphology

Summary Microtubule (MT) distribution during the cell cycle, especially spindle organization, has been investigated using immunofluorescence light microscopy in cultured cells of two higher plant species, soybean (angiosperm) and black spruce (gymnosperm). In soybean, the prophase and metaphase spindles were different in morphology and structure. The prophase spindle covering the nucleus was barrel-shaped and MTs extended between poles. The metaphase spindle consisted mainly of short MT bundles on either side of the chromosome mass. During prometaphase, the polarity and shape of the prophase spindle disappeared, suggesting that the metaphase spindle is newly formed in prometaphase and not derived from the prophase spindle. A striking feature of MT organization in black spruce was sharply defined poles during prometaphase and anaphase. They were located close to the cell edge, suggesting that a structure in the cytoplasm or associated with the plasma membrane is responsible for their formation. In black spruce the metaphase spindle was long with pointed poles and MT fir tree structures. In contrast, the metaphase spindle of soybean was short with very broad poles and lacked MT fir trees. These results suggest that MT fir tree structure may not be necessary for a functional spindle.     

A β-lactamase gene of Fusarium oxysporum alters the rhizosphere microbiota of soybean

The rhizosphere is a multitrophic environment, and for soilborne pathogens such as Fusarium oxysporum, microbial competition in the rhizosphere is inevitable before reaching and infecting roots. This study established a tritrophic interaction among the plant growth-promoting rhizobacterium Burkholderia ambifaria, F. oxysporum and Glycine max (soybean) to study the effects of F. oxysporum genes on shaping the soybean microbiota. Although B. ambifaria inhibited mycelial growth and increased bacterial propagation in the presence of F. oxysporum, F. oxysporum still managed to infect soybean in the presence of B. ambifaria. RNA-Seq identified a putative F. oxysporum secretory β-lactamase-coding gene, FOXG_18438 (abbreviated as Fo18438), that is upregulated during soybean infection in the presence of B. ambifaria. The ∆Fo18438 mutants displayed reduced mycelial growth towards B. ambifaria, and the complementation of full Fo18438 and the Fo18438 β-lactamase domain restored mycelial growth. Using the F. oxysporum wild type, ∆Fo18438 mutants and complemented strains with full Fo18438, Fo18438 β-lactamase domain or Fo18438 RTA1-like domain for soil inoculation, 16S rRNA amplicon sequencing revealed that the abundance of a Burkholderia operational taxonomic unit (OTU) was increased in the rhizosphere microbiota infested by the strains with Fo18438 β-lactamase domain. Non-metric multidimensional scaling and PICRUSt2 functional analysis revealed differential abundance for the bacterial β-lactam-related functions when contrasting the genotypes of F. oxysporum. These results indicated that the Fo18438 β-lactamase domain provides F. oxysporum with the advantage of growing into the soybean rhizosphere, where β-lactam antibiosis is involved in microbial competition. Accordingly, this study highlights the capability of an F. oxysporum gene for altering the soybean rhizosphere and taproot microbiota.     

Inheritance of reduced linolenic acid content in soybean seed oil

 Linolenic acid is the unstable component of soybean [Glycine max (L.) Merr.] oil that is responsible for the undesirable odors and flavors commonly associated with poor oil quality. Two mutants, M-5 and KL-8, have been identified that have lower linolenic acid levels in the seed oil than the ‘Bay’ cultivar. Our objective was to determine the relationships between the genetic systems controlling linolenic acid in these mutants. Reciprocal crosses were made between the mutants and ‘Bay’, and between the two mutants. No maternal effect for linolenic acid content was observed from the analysis of F₁ seeds in any of the crosses. The data for linolenic acid content in F₂ seeds of M-5בBay’ and KL-8בBay’ crosses satisfactorily fit a 1 : 2 : 1 and 3 : 1 ratio, respectively. For the M-5×KL-8 cross, segregation observed from the analysis of F₂ seeds for linolenic acid content satisfactorily fit a ratio of 3 more than either mutant: 12 within the range of the two mutants: 1 less than either mutant. The segregation ratio of F₂ seeds and the segregation of F₃ seeds from F₂ plants indicated that M-5 and KL-8 have alleles at different loci that control linolenic acid content. The allele in KL-8 has been designated as fanx (KL-8) to distinguish it from fan (M-5). The low linolenic acid segregates with the genotype fanfanfanxfanx provide additional germplasm to reduce the linolenic acid content from the seed oil of soybean. Received: 18 December 1995 / Accepted: 12 July 1996     

Effects of aluminium on tap-root elongation of soybean (Glycine max), cowpea (Vigna unguiculata) and green gram (Vigna radiata) grown in the presence of organic acids

The role of fulvic, malic, and oxalic acids in alleviating the toxic effects of aluminium (Al) on tap-root elongation of soybean cv. Fitzroy, cowpea cv. Vita 4, and green gram cv. Berken was studied. Treatments consisted of a factorial combination of four Al concentrations (0, 12.5, 25 and 50 µM as Al(NO₃)₃·9H₂O) and two concentrations either of malic or oxalic acid (0, 50 µM) or fulvic acid (0, 65 mg L^-1 of organic carbon). The free monomeric Al in solution was determined using a pyrocatechol violet procedure which distinguishes between monomeric and organically complexed Al. Fulvic acid completely alleviated the toxic effect of Al at all concentrations on soybean and cowpea and at concentrations <25 µM on green gram. The non-toxic Al-fulvate complex remained in solution. Both malic and oxalic acid, at the concentrations tested, failed to alleviate Al toxicity on any species; a much higher proportion of the added Al remained in monomeric form in the presence of these acids.     

The Effect of Potassium Nitrate on the Reduction of Phytophthora Stem Rot Disease of Soybeans, the Growth Rate and Zoospore Release of Phytophthora sojae

The effects of potassium nitrate (KNO₃) application on Phytophthora stem rot disease reduction of Glycine max (L.) Merr. cvs. Chusei-Hikarikuro and Sachiyutaka, and mycelium growth and zoospore release of a Phytophthora sojae isolate were investigated under laboratory conditions. The application of 4–30 m m KNO₃ prior to inoculation greatly reduced incidence of disease in the two soybean cultivars. Although a concentration of 20–30 m m KNO₃ led to a slight decrease in the growth rate of the PJ-H30 isolate on PDA medium, no significant relationship was observed between inhibition of the growth rate and disease reduction on application of 0.4–10 m m KNO₃. Disease suppression recorded in laboratory experiments using pathogen mycelium was due to the response of plant tissues rather than a direct inhibition of pathogen hyphal growth by the application of KNO₃. The extent of disease reduction was related to increased potassium concentration in plants of the two cultivars (except for some cases involving cv. Sachiyutaka), suggesting that differences existed between the two cultivars in terms of the effect of KNO₃ application on disease suppression. Scanning electron microscopic observation with fresh samples indicated marked accumulation of potassium at the penetration-stopping sites of P. sojae in the cortex layer of soybean plants treated with 30 m m KNO₃, compared with the non-treated control plants. The presence of 0.4–30 m m KNO₃ decreased the release of zoospores. These results suggest the possibility of applying a solution containing 20–30 m m of KNO₃ to decrease the incidence of disease in agricultural fields by the response of plant tissues to KNO₃.     

Inheritance of two independent isozyme variants in soybean plants derived from tissue culture

Summary Soybean [Glycine max (L.) Merr.] plants were regenerated via somatic embryogenesis from nine soybean cultivars. Our objective was to identify and characterize genetically novel mutations that would further our understanding of the soybean genome. Variant isozyme patterns were observed in two independent tissue culturederived lines. Genetic analyses were conducted on these two isozyme variants, and they were heritable. No variant isozyme patterns were evident in control (parental) soybean lines. In the cultivar BSR 101, a mutation of Aco2-b (aconitase) to a null allele was detected. The Aco2-bn mutant, Genetic Type T318, had not been previously observed in soybean. In the Chinese cultivar Jilin 3 (PI 427.099), a chlorophyll-deficient plant was identified that also lacked two mitochondrial malate-dehydrogenase (Mdh null) isozyme bands. These two mutant phenotypes, chlorophyll-deficient and Mdh null, were found to cosegregate. The Jilin 3 mutant, Mdh1-n (Ames 1) y20 (Ames 1) Genetic Type T317, was allelic to three chlorophyll-deficient, Mdh1 null mutants [Mdh1-n (Ames 2) y20 (Ames 2) (T323), Mdh1-n (Ames 3) y20 (Ames 3) (T324), and Mdh1-n (Ames 4) y20 (Ames 4) (T325)] previously identified from a transposon-containing soybean population, and to a chlorophyll-deficient, Mdh1 null mutant [Mdh1-n (Urbana) y20 (Urbana) k2, Genetic Type T253] which occurred spontaneously in soybean. The recovery of two isozyme variants from progeny of 185 soybean plants regenerated from somatic embryogenesis indicates the feasibility of selection for molecular variants.     

Emergence and growth of two non-nodulated soybean genotypes (Glycine max (L.) Merr.) in response to soil acidity

Toxic levels of extractable soil Al limit production of important crops in many areas of the world. The nature of the limitation in soybeans is not completely understood. Our objectives were to investigate the cause of acid-soil-induced delays in seedling emergence, the effect of acidity on productivity in non-nodulated soybeans and further test the Al tolerance of PI 416,937 compared to a sensitive control, Essex. Growth characteristics of the two genotypes through the flowering stage were measured on a Corozal clay (Aquic Tropudult) in Puerto Rico which had been differentially limed to provide a wide range of soil Al. Early growth was also studied in the laboratory using soil from the field experiment. Highly acidic soil conditions, coupled with high Al levels, reduced growth in both Essex and PI 416,937. The principal factor responsible for delayed emergence in the high Al soil was not delayed radicle initiation, but delayed initiation of hypocotyl elongation. Hypocotyl initiation was highly associated with rate of tap root growth, with the former possibly determined by the latter, because a minimum tap root length of 60 mm was required in both high and low Al soils before hypocotyl initiation commenced. In seedlings, the high acidity reduced root more than shoot growth. By 44 days after planting (DAP), however, soil acidity had reduced shoot growth greatly. Although the soybean plants were not nodulated, foliar N levels and shoot growth were decreased by high Al levels, indicating that interference with N fixation may not be the sole mechanism by which nitrogen accumulation and plant growth is reduced in the field.Joint contribution from the USDA, ARS, Tropical Agriculture Research Station, Mayaguez, PR; USDA, ARS, Soybean and Nitrogen Fixation Research Unit, Raleigh, NC, and the Agricultural Experiment Station-University of Puerto Rico (AES-UPR), Rio Piedras, PR.Joint contribution from the USDA, ARS, Tropical Agriculture Research Station, Mayaguez, PR; USDA, ARS, Soybean and Nitrogen Fixation Research Unit, Raleigh, NC, and the Agricultural Experiment Station-University of Puerto Rico (AES-UPR), Rio Piedras, PR.     

Biochemical side effects of genetic transformation of pineapple

Evaluations were made during 30 days of in vitro-plantlet hardening. Transformed (bar, chitinase, ap24 transgenes) and non-transformed plantlets were compared. Both groups of plantlets were similar in regard with plant height and weight and peroxidase activity. However, statistical significant changes, caused by transformation, were recorded in levels of malondialdehyde, other aldehydes, chlorophyll (a, b, total), phenolics (free and cell wall-linked) and proteins.     

中国分类学文献中Livistona saribus 之订正

通过调查,对Livistona speciosa的等模式、L.saribus的等新模式与中国分类学文献中（如《海南植物志》、《中国植物志》、《福建植物志》、《云南植物志》）的L.speciosa、L.saribus作比较,证实中国分类学文献将L.saribus、L.speciosa相混,中国分类学文献中的L.saribus、L.speciosa均为L.speciosa Kurz。美丽蒲葵L.spe-ciosa的叶的裂片先端浅裂、坚挺,果倒卵形、椭圆形至卵形,长度多于2.5cm,直径多于2cm;大叶蒲葵L.sari-bus（Lour.）Merr.ex A.Chev.的叶的裂片先端深裂、下垂,果球形至近球形,直径少于1.8cm。增补了L.sari-bus的等新模式。