Relationship between growth irradiance and the xanthophyll cycle pool in the diatom Nitzschia palea

The size and de-epoxidation state of the xanthophyll cycle pool was measured in cultures of Nitzschia palea grown at six fluence rates in continuous light or with a 12 h photoperiod. In both series the size of the pool increased with increasing irradiance. The de-epoxidized form, diatoxanthin, was only present at fluence rates saturating for growth. The portion of diadinoxanthin, which was not readily de-epoxidized in saturating light, was constant and not related to the size of the pool. In the culture grown in a light-dark cycle at 300 μmol photons m^-2 s^-1 (PAR) increasing de-epoxidation took place in the latter half of the photoperiod, when the rate of photosynthesis was decreasing. A rapid, spectrophotometric method for measuring the extent of de-epoxidation of the xanthophyll cycle pool in a culture of diatoms is described. Upon addition of a small volume of hydrochloric acid to an extract of pigments in 90% acetone, the absorbance at 480 nm is reduced. The size of the reduction is a measure of the state of the xanthophyll cycle pool, since the absorbance of diatoxanthin is reduced by 5%, but the absorbance of diadinoxanthin by 87% due to an epoxide-furanoid rearrangement, which causes the absorption spectrum to be shifted by ca 20 nm towards shorter wavelengths.     

Characteristics of photosynthetic carbon metabolism of spikelets in rice

In lemmas and paleae of rice, the amount of pyruvate, Pi dikinase (PPDK) protein increased dramatically 6 d after anthesis and this change was consistent with that in the activity of PPDK. Since lemmas and paleae at this stage also showed high activities of the other marker enzymes of C4 pathway including phosphot enolpyruvate carboxylase (Imaizumi et al. (1990) Plant Cell Physiol 31: 835–843), photosynthetic carbon metabolism with lemmas at this stage were characterized. In a 14C pulse-12C chase study by photosynthetic CO2 fixation, about 35% and 25% of 14C fixed in lemmas were incorporated initially into 3-phosphoglycerate (3-PGA) and C4 acids, respectively. This suggests that lemmas participate mainly in C3-type photosynthetic metabolism, but that lemmas may also participate in the metabolism of C4 acids to some extent. To clarify this possibility, large amounts of 14C-labeled C4 acids were synthesized in vivo by a light-enhanced dark CO2 fixation (LED) method and the fate of 14C in C4 acids in the light was investigated. The percentage distribution of 14C in C-4 position of malate was about 90% and 83% after 10 s of photosynthetic 14CO2 fixation and 110 s of LED, respectively. Some of the 14C incorporated into C4 acids was transferred into 3-PGA and sugar phosphates. The possibility of direct fixation of CO2 by phosphot enolpyruvate carboxylase and metabolic pathway of CO2 released by decarboxylation of malate produced were discussed.     

Crinkly4 receptor-like kinase is required to maintain the interlocking of the palea and lemma, and fertility in rice, by promoting epidermal cell differentiation

The palea and lemma are unique organs in grass plants that form a protective barrier around the floral organs and developing kernel. The interlocking of the palea and lemma is critical for maintaining fertility and seed yield in rice; however, the molecules that control the interlocking structure remain largely unknown. Here, we showed that when OsCR4 mRNA expression was knocked down in rice by RNA interference, the palea and lemma separated at later spikelet stages and gradually turned brown after heading, resulting in the severe interruption of pistil pollination and damage to the development of embryo and endosperm, with defects in aleurone. The irregular architecture of the palea and lemma was caused by tumour-like cell growth in the outer epidermis and wart-like cell masses in the inner epidermis. These abnormal cells showed discontinuous cuticles and uneven cell walls, leading to organ self-fusion that distorted the interlocking structures. Additionally, the faster leakage of chlorophyll, reduced silica content and elevated accumulation of anthocyanin in the palea and lemma indicated a lesion in the protective barrier, which also impaired seed quality. OsCR4 is an active receptor-like kinase associated with the membrane fraction. An analysis of promoter::GUS reporter plants showed that OsCR4 is specifically expressed in the epidermal cells of paleas and lemmas. Together, these results suggest that OsCR4 plays an essential role in maintaining the interlocking of the palea and lemma by promoting epidermal cell differentiation.     

一个水稻内颖退化突变体的形态特征及基因的精确定位

水稻产量和品质受花器官发育的直接影响,因此对水稻颖花发育机理的研究将有助于水稻产量提高和品质的改良。文章利用60Coγ射线辐照亲本8PW33(籼稻背景)获得一个性状能稳定遗传的内颖退化突变体(编号:MU102),并对其农艺性状和花器官进行了观察和分析。结果显示,相对于野生型,该突变体的株高、每穗总粒数及剑叶宽均显著增加,而结实率则显著降低,差异均达显著水平。解剖镜下观察表明,该突变体内颖退化,外颖弯曲呈现镰刀状,其余器官与野生型表型基本一致。扫描电镜观察显示,突变体与野生型叶片维管束的结构组成以及外颖表皮细胞组成、排列均正常,没有明显差异;与野生型相比,突变体内颖表皮细胞排列较为紧密,推测可能是内颖收缩退化导致的。遗传分析显示该突变性状是由隐性单基因控制,并命名为pd2。利用实验室现有的SSR分子标记将PD2基因定位于水稻第9号染色体上,通过进一步扩大群体和开发新的Indel标记,将PD2基因定位在2个Indel标记之间,两者间的物理距离大约是82 kb。在该物理区间内有一个已经克隆的内颖发育基因REP1,经过测序和比对分析,推测REP1与PD2为等位基因。     

水稻内颖畸形或缺失基因OsAPP1的图位克隆及表达分析

在育种基地材料中发现一株内颖畸形或缺失(abnormal or absent palea)突变体,将其命名为app1。该突变体在营养生长时期发育正常,但抽穗后突变体表现出内颖畸形(比外稃短导致颖壳不闭合,或者出现两个内稃)或缺失,其花粉育性为55.52%,结实率为6.48%,千粒重为10.811 g,种子发芽率为55.21%。以突变体app1与日本晴杂交构建了F1和F2群体,F1颖壳表型正常,F2群体出现内颖畸形和正常表型分离,内颖正常和突变表型分离比例为3∶1,表明app1内颖突变表型由单隐性核基因控制。以F2为分离群体,将app1精细定位于第3染色体上,位于分子标记ID4231和ID4246之间,遗传距离1.3 cM,对应物理距离为13.2 kb。该区段内完全包含1个开放阅读框,包含两个部分开放阅读框,经过测序分析发现候选基因LOC_Os03g11614启动子区发生点突变和245 bp缺失,qRT-PCR分析证实LOC_Os03g11614为OsAPP1基因。已有报道LOC_Os03g11614编码OsMADS1,是调控水稻花器官发育的重要明星基因,其不同位置的突变可以导致叶状颖壳和不育、以及控制籽粒大小。与3000份水稻种子资源SNP/Indel变异类型对比分析发现,突变体app1启动子的突变完全不同于现已OsMADS1研究报道突变类型,且与数据库中的自然突变类型多数不同。因此,本研究发现的app1突变体,是以往报道中从未出现的OsMADS1启动子发生突变的新型突变,且该类突变导致了其降低表达量,并产生了不同于前人研究的新表型,这为深入研究OsMADS1基因在水稻花器官发育中的功能提供了新的种质资源和思路。     

Effect of Husk morphology on grain development and topography in rice

Kernels grown within loosened glumes in three varieties of paddy were darker in color and had a smoother surface than those grown under normal conditions. The thickness of the pericarp plus seed coat layers was 33.6 ±2.8 µm, and the thickness of the aleurone layers was 21.7 ± 2.5 µm in grains of the first type, while in the normal grains, these dimensions were 13.0 ± 1.4 and 26.9 ± 2.9 µm respectively. The kernels which developed within loosened glumes tended to taper towards the distal end. They were lighter in weight than normal grains by 32 to 67 percent, the weight loss being less in the bolder variety. The lemma-palea interlocking depth was positively correlated with the groove depth on the kernel and with the clearance between husk and kernel. All three parameters showed a positive correlation with grain breadth. A low lemma-palea interlocking depth and a smaller clearance between husk and kernel are technologically desirable characteristics in rice. The reclasping of the two glume components after pollination was essential for the normal development of the rice grain.     

Cd2+ affects the growth,hierarchical structure and peptide composition of the biosilica of the freshwater diatom Nitzschia palea (Kützing) W. Smith

Biosilica from diatoms is formed at ambient conditions under the control of biological and physicochemical processes. The changes in growth and biosilica formation through uptake of different concentrations of Cd²⁺ by the diatom Nitzschia palea (Kützing) W. Smith was investigated, correlating Cd²⁺ effects to changes in the biosilica nanostructure and the relative content of the encapsulated biomolecules. Diatom growth rates at different Cd²⁺ concentrations (as 1, 2, 3, 4, and 5 × 10^?1 mg L^?1 CdCl₂) were studied in order to determine the concentrations at which sublethal effects were visible, allowing the harvest of sufficient diatom cells for further experiments. We found a clear correlation between the Cd²⁺ concentrations and both the nanostructure of the biosilica and content of encapsulated peptides. Cd²⁺ induced biosilica deformation was assessed by scanning electron microscopy and attenuated total reflectance‐Fourier Transformed Infrared Spectroscopy (FTIR), revealing that micromorphological changes in frustule features (striae, costae, pores) and nanostructural modifications (structure of the silica and conformation of the encapsulated peptides) occurred at applied Cd²⁺ concentrations of 2 and 3 × 10^?1 mg L^?1. In particular the FTIR contribution of peptides decreased at elevated Cd²⁺ concentrations, whereas shifts in wave number of several relevant organic bonds as C = O stretching (1765 cm^?1) and possibly hydrated sulfate (1160, 1110 and 980 cm^?1) were assigned. Additional analysis of the amide I band showed a relative increase in β‐sheet structure (1680–1620 cm^?1) when Cd²⁺ concentration increased. Cadmium uptake clearly affected the molecular ordering of the biosilica in Nitzschia palea, most probably by interfering in biological or physicochemical processes involved in diatom biosilicification.     

Seed dormancy and longevity in <Emphasis Type="Italic">Stipa tenacissima</Emphasis> L. (Poaceae)

In the present paper we studied the life history traits related to seed germination of Stipa tenacissima, a key species in semiarid environments of western Mediterranean areas. S. tenacissima is a perennial tussock grass, which has traditionally been considered to expand mainly by vegetative propagation with little or no sexual reproduction. We analysed seed longevity as well as the type of seed dormancy and the role of the seed covers from seeds collected from different populations in SE Spain. We also studied the variation in seed germinability among populations, individuals, and years and the ability of seeds of S. tenacissima to form soil seed banks. There was significant variation in seed germination among individuals, populations and years. Lemma and palea were the main factor controlling these differences since their removal promoted higher and faster germination and eliminated the differences in germination parameters among populations. However, the control of dormancy by lemma and palea was independent of their weight, suggesting that their chemical nature plays a more important role than does size in controlling seed germination. Mechanical scarification treatments (via abrasion with sand) did not affect seed germination. The decay in seed germinability two years after seed collection and the low density of viable seeds in soils one year after seed dispersal indicated that S. tenacissima forms transient soil seed banks.