南方砂梨返花过程中内源激素含量变化及其与秋季返花的关系

为探讨花芽内源激素含量变化与返花的关系,以砂梨品种‘丰水’、‘翠冠’为材料,研究了砂梨采果后返花过程中花芽内源激素(IAA、GA3、ABA)含量变化,以及早期落叶和秋季返花特征。结果表明:(1)在采果后至返花过程中,两个品种梨花芽中内源激素IAA和GA3含量都呈逐渐缓慢下降趋势;花芽ABA含量的动态变化成升-降-升的"S"曲线。(2)花芽返花受3种激素的动态平衡控制,花芽IAA/ABA、GA3/ABA和(IAA+GA3)/ABA值变化趋势均呈相似的"S"形曲线,IAA/ABA、GA3/ABA和(IAA+GA3)/ABA值增加,花芽返花;比值降低,花芽逐渐步入休眠期。(3)砂梨的落叶率与返花率呈极显著正相关关系,花芽中IAA/ABA比值与砂梨落叶率和返花率相关系数分别为0.805、0.774,相关性均达到显著水平。研究认为,梨返花与早期落叶密切相关,受花芽内源激素IAA、GA3、ABA动态平衡控制;早期落叶降低了花芽中ABA的含量,从而使花芽内生长促进型激素占主导地位,阻止自然休眠的花芽进入休眠或促使进入浅休眠部分花芽解除休眠,所以出现秋季返花现象。     

桃花芽自然休眠期间水孔蛋白基因的转录表达

以10年生大田栽培及3年生盆栽曙光油桃花芽为试材,利用荧光定量PCR测定了油桃休眠及休眠解除期间(2009年9月15日-2010年1月15日)曙光油桃水孔蛋白基因δTIP1、PIP1;1的表达量,以及低温胁迫下的转录表达.结果表明:在油桃休眠及休眠解除期间,曙光油桃PIP1;1的转录水平呈现持续增高趋势,且1月的高水平表达使水分通过液泡膜和细胞质膜流出,减少了芽体水分含量,阻止细胞内冰晶的形成,从而抵御冻害;可溶性糖、可溶性蛋白、脯氨酸含量均达到最高,防止细胞的脱水伤害.低温处理2周后高水平表达说明PIP1;1为冷诱导基因.δTIP1的转录水平在休眠期间呈现波动性变化,至休眠解除时大幅度增高,这可能与休眠解除时,其上调表达被休眠解除信号及植物活性的增强所诱导有关.低温处理2周后,其表达没有升高,说明δTIP1并非冷诱导基因.     

‘黄花’梨及其芽变‘绿黄花’梨HHT基因克隆与表达分析

该试验以砂梨品种‘黄花’梨（果皮褐色）及其芽变‘绿黄花’梨（果皮绿色）盛花后第8周的果皮为试材,利用常规PCR和巢式PCR技术克隆了ω 羟基棕榈酸O 阿魏酰转移酶（ω hydroxypalmitate O feruloyl transferase, HHT）基因cDNA的全长,命名为 PpyHHT（登录号为KX131155）。序列分析结果表明,该基因开放阅读框（ORF）为1 335 bp,编码444个氨基酸。生物信息学分析显示,推定的PpyHHT蛋白质相对分子质量为49.91 kD,等电点是4.75,与白梨相似性高达98%,亲缘关系最近。实时荧光定量PCR（qRT PCR）表达分析显示,2种梨果皮中 PpyHHT基因在盛花后6~9周的4个转色关键期表达量不断变化,在‘黄花’梨果皮中的表达量明显高于‘绿黄花’梨。推测 PpyHHT基因可能参与砂梨果实褐色/绿色性状的形成。     

梨树花芽休眠解除与活性氧代谢的关系

梨树(Pyrus bretschneideri Rehd.)自然休眠和休眠解除时,花芽的活性氧代谢发生变化.O2-·产生速率和H2O2的含量在休眠期间上升,在休眠后期下降.抗氧化系统中SOD活性在自然休眠期呈下降趋势,自然休眠结束活性上升.POD和CAT活性在自然休眠期上升.抗氧化物质AsA和GSH的含量随休眠进行而下降,休眠解除过程中重新升高.APX和GR的活性在休眠期间活性下降,休眠结束活性迅速上升.这些结果表明:花芽的休眠与活性氧的代谢有很大关系.     

漳州水仙ZDS 基因cDNA克隆及其表达分析

采用RACE技术从漳州水仙‘金盏银台’Narcissus tazetta var. chinensis花器官总RNA中克隆ZDS的cDNA序列,用相关软件进行序列分析,并利用实时荧光定量技术检测ZDS基因在各水仙品种不同花器官的表达。序列分析表明,ZDS基因cDNA全长2189 bp,其中包含69 bp 5'非编码区,395 bp 3'非编码区,1725 bp编码区（编码574个氨基酸,分子量约63.6 kDa）,命名为Ntzds （GenBank登录号: EU573238）,其编码的氨基酸序列（ACB87206.1）与喇叭水仙（CAA12062.1）、葡萄（XP_002277348.21）和温州蜜柑（ABC33728.1）ZDS基因编码产物的相似性分别为97%、85%和83%。实时荧光定量PCR分析表明,Ntzds基因在漳州水仙‘金盏银台’、‘Minnow’、‘Fortissimo’中均有表达,且同一品种中副冠的表达量高于花瓣;随着花色的加深,其转录水平也逐渐趋高。     

樱胚珠发育调控基因PrseSTK在单瓣与重瓣花中的表达比较

用同源克隆方法,从日本晚樱（Prunus lannesiana）花芽中克隆出了PrseSTK基因的cDNA全长,GenBank登录号为GU332504。其包括1个共669 bp的完整开放阅读框,编码222个氨基酸和1个终止密码子。同源序列比对和分子系统进化分析表明,PrseSTK是拟南芥的STK同源基因,其编码蛋白的C末端拥有2个高度保守模体：AG motif Ⅰ和Ⅱ,属D类MADS-box转录因子。其在花器官中表达的组织特异性分析表明,在单瓣‘大岛樱’中,PrseSTK主要在雄蕊和雌蕊中表达;但在重瓣品种‘普贤像’中,其在萼片、雄蕊和叶化雌蕊中均有表达。其在2个品种4轮花器官中的表达呈现明显的差异,并与拟南芥STK基因表达的组织特异性也有一定的差别;其在花萼中的异位表达可能与重瓣品种萼筒异位子房的发育调控相关。     

甘蓝型油菜种子中油体的超微结构及蛋白质组分析

以甘蓝型油菜（Brassica napus L.）含油量较高的品种‘ZS11’、含油量中等的品种‘Westar’和‘Topas’以及含油量较低的品种‘ZS10’为实验材料,通过超微结构观察和统计,比较分析不同品种种子中油体形态、大小和数量的差异。研究结果显示,品种‘ZS11’种子子叶细胞油体排列致密,形态较小,大部分油体的直径低于1 μm;而在含油量中等或较低的品种中,种子子叶细胞油体排列均显疏松,其中‘Westar’和‘Topas’的油体较大,而‘ZS10’的油体大小不一。本研究还通过双向电泳分析进一步检测了‘Westar’和‘ZS11’种子中总蛋白和油体蛋白的差异表达情况。结果显示,‘Westar’和‘ZS11’种子总蛋白双向电泳图谱中,表达量具有2倍以上差异的蛋白质点共有57个;其中在‘Westar’中特异表达的种子总蛋白质点有24个,在‘ZS11’中有23个。在上述2个品种油体蛋白双向电泳图谱中,表达量具有2倍以上差异的蛋白质点共有52个,在品种‘Westar’中特异表达的有2个,‘ZS11’中有13个。表明不同含油量的油菜品种种子在油体的结构和蛋白组份上均存在差异。     

休眠期间油桃花芽碳水化合物代谢及其相关基因的表达变化

以十年生大田和三年生盆栽‘曙光’油桃花芽为材料,分别测定了其休眠期碳水化合物含量、糖代谢相关基因的季节性表达及低温处理下相关基因的表达变化,旨在探讨碳水化合物及低温与休眠的关系。结果表明：休眠期间可溶性糖（主要是蔗糖）含量逐渐增加,淀粉含量则呈相反趋势。糖代谢相关基因表达明显不同：腺苷二磷酸葡萄糖焦磷酸化酶基因口GPase）无明显变化;组氨酸H3基因（HisH3）和己糖激酶I基因（胱,）在进入内休眠前有明显上升,蔗糖合酶基因（SuSy）则与之相反;尿苷二磷酸葡萄糖焦磷酸化酶（UGPase）表达总体上呈上调趋势,在进入内休眠后稍有下调。表明进入内休眠后,依赖HKl的糖信号转导途径起重要作用。在4℃处理后,与细胞分裂有关的基因HisH3含量急剧升高,而后下降,说明细胞分裂的减少并不是休眠期间抑制生长的原因;UGPase表现出与内休眠期一致的变化趋势,说明对低温有一定的适应性。     

黄花梨bZIP的cDNA克隆与表达分析

为探讨黄花梨(Pyrus pyrifolia‘Huanghua’)PpbZIP基因的功能,根据同源基因bZIP从黄花梨花芽中克隆到PpbZIP基因(GenBank登录号:KC951877)。PpbZIP基因的全长cDNA为1843 bp,其中开放阅读框长度1227 bp,编码408个氨基酸,与同为蔷薇科的苹果bZIP蛋白序列的同源性高达92%。PpbZIP基因的QRT-PCR分析表明,PpbZIP基因在黄花梨花芽从休眠到休眠解除后的表达量呈先升高后降低的趋势。这表明PpbZIP参与了黄花梨花芽休眠过程的调控。     

不同微型月季品种扦插生根效果综合评价

为了筛选易生根的优良微型月季品种,采用主成分分析、隶属函数和聚类分析方法,对7个微型月季品种扦插的7个根系形态指标进行综合评价。结果表明,微型月季品种之间的生根能力存在差异,7个根系形态指标用3个相互独立的综合指标代替,即第1主成分、第2主成分和第3主成分,7个微型月季品种扦插生根效果依次为：‘淑女’、 ‘红色恋人’、‘绝恋’、‘女儿红’、‘维纳斯’、‘春色’、‘灵感’,其中‘淑女’在种苗生产上采用常规扦插方法即可保证较高的插穗成活率。     

Characterization of 10 MADS-box genes from Pyrus pyrifolia and their differential expression during fruit development and ripening

We cloned 10 Japanese pear (Pyrus pyrifolia) MIKC-type II MADS-box genes, and analyzed their expression during fruit development and ripening. PpMADS2-1 was APETALA (AP)1-like; PpMADS3-1 was FRUITFULL (FUL)/SQUAMOSA (SQUA)-like; PpMADS4-1 was AGAMOUS-like (AGL)6; PpMADS5-1 and PpMADS8-1 were SUPPRESSOR OF OVEREXPRESSION OF CONSTANS (SOC)-like; PpMADS9-1, PpMADS12-1, PpMADS14-1 and PpMADS16-1 were SEPALLATA (SEP)-like; while PpMADS15-1 was AGL/SHATTERPROOF (SHP)-like. Phylogenetic analysis showed their grouping into five major clades (and 10 sub-clades) that was consistent with their diverse functional types. Expression analysis in flower tissue revealed their distinct putative homeotic functional classes: A-class (PpMADS2-1, PpMADS3-1, PpMADS4-1, and PpMADS14-1), C-class (PpMADS15-1), E-class (PpMADS9-1, PpMADS12-1, and PpMADS16-1) and E (F)-class (PpMADS5-1 and PpMADS8-1). Differential gene expression was observed in different fruit tissues (skin, cortex and core) as well as in the cortex during the course of fruit development and ripening. Collectively, our results suggest their involvement in the diverse aspects of plant development including flower development and the course of fruit development and ripening.     

ParSOC1, a MADS-box gene closely related to Arabidopsis AGL20/SOC1, is expressed in apricot leaves in a diurnal manner and is linked with chilling requirements for dormancy break

Dormancy break is a physiological phenomenon associated with the ability of plants to cope with changing environmental conditions and adjust their growth habits accordingly. In order to understand the potential role of genes in the control of dormancy break ParSOC1, a distinct apricot MADS-box gene which is most closely related to the AGL20/SOC1 MADS-box family was studied in several apricot cultivars that differ in their chilling requirements. The ParSOC1 gene is expressed in a diurnal manner and is highly polymorphic among apricot cultivars in the transcribed region upstream to the putative ATG translation initiation site. Genotyping of 48 different apricot cultivars revealed 13 different ParSOC1 alleles. By associating the chilling requirements of the apricot cultivars with their ParSOC1 genotype, it was possible to demonstrate a significant correlation between the presence of specific ParSOC1 alleles and chilling requirements. The data provided suggest that ParSOC1 or a gene in its close proximity could be involved in the regulation of dormancy break of vegetative shoots in apricot.     

Histone modification and signalling cascade of the dormancy‐associated MADS‐box gene,PpMADS13‐1, in Japanese pear (Pyrus pyrifolia) during endodormancy

Dormancy‐associated MADS‐box (DAM) genes play an important role in endodormancy phase transition. We investigated histone modification in the DAM homolog (PpMADS13‐1) from Japanese pear, via chromatin immunoprecipitation–quantitative PCR, to understand the mechanism behind the reduced expression of the PpMADS13‐1 gene towards endodormancy release. Our results indicated that the reduction in the active histone mark by trimethylation of the histone H3 tail at lysine 4 contributed to the reduction of PpMADS13‐1 expression towards endodormancy release. In contrast, the inactive histone mark by trimethylation of the histone H3 tail at lysine 27 in PpMADS13‐1 locus was quite low, and these levels were more similar to a negative control [normal mouse immunoglobulin G (IgG)] than to a positive control (AGAMOUS) in endodormancy phase transition. The loss of histone variant H2A.Z also coincided with the down‐regulation of PpMADS13‐1. Subsequently, we investigated the PpMADS13‐1 signalling cascade and found that PpCBF2, a pear C‐repeated binding factor, regulated PpMADS13‐1 expression via interaction of PpCBF2 with the 5′‐upstream region of PpMADS13‐1 by transient reporter assay. Furthermore, transient reporter assay confirmed no interaction between the PpMADS13‐1 protein and the pear FLOWERING LOCUS T genes. Taken together, our results enhance understanding of the molecular mechanisms underlying endodormancy phase transition in Japanese pear.     

Chill-responsive dehydrins in blueberry: Are they associated with cold hardiness or dormancy transitions?

To survive winters, woody perennials of temperate zones must enter into endodormancy. Resumption of spring growth requires sufficient exposure to low temperature (chill units, CUs) in winter (chilling requirement), which also plays a role in the development of cold hardiness (cold acclimation). Physiological studies on dormancy breaking have focused on identifying markers, such as appearance or disappearance of proteins in response to varying degrees of chill unit accumulation. However, whether these changes are associated with dormancy transitions or cold acclimation is not clear. In the present study, greenhouse-grown blueberry (Vaccinium section Cyanococcus) plants were used to address this question. Three blueberry cultivars, Bluecrop, Tifblue, and Gulfcoast having chilling requirement of approximately 1 200, 900 and 600 CUs, respectively, were first exposed to 4°C for long enough to provide chill units equivalent to one-half of their respective chilling requirement. This treatment was expected to result in cold acclimation. A fraction of plants was then subjected to a 15/12°C (light/dark) regime for 2 weeks, a treatment expected to be “dormancy-neutral” but cause deacclimation. Before and after each treatment, cold hardiness and dormancy status of floral buds were determined; proteins were extracted from the buds collected on the same sampling date, and separated by one-dimensional SDS-PAGE. Dehydrin-like proteins were identified by immunoblotting, using anti-dehydrin antiserum. Results indicate that the chilling treatment resulted in cold acclimation as indicated by increased bud hardiness in all three cultivars. Data also indicate a distinct accumulation of three dehydrin-like proteins of 65, 60, and 14 kDa during cold acclimation. The cold hardiness and levels of dehydrin proteins decreased during the exposure to 15/12°C for 2 weeks. Results also confirmed that this treatment had no negative effect on chill unit accumulation. Densitometric scans of protein gels indicated a close association between the abundance of dehydrins and degree of cold hardiness in these cultivars. In addition, levels of the dehydrin proteins and cold hardiness remained about the same between 100% and >100% satisfaction of chilling requirement. These results suggest that changes in dehydrin expression are more closely associated with cold hardiness than with dormancy transitions.     

PP2C相关基因在砂梨休眠进程中的表达分析

对植物蛋白磷酸酶2C(PP2C)相关基因在砂梨Pyrus pyrifolia品系休眠进程中的表达进行分析。结果表明,砂梨PP2C相关基因与李属PP2C基因高度同源。在梨花芽休眠过程中不同PP2C基因调控的作用不同, PP2C-37-1、PP2C-37-2、PP2C-51-1、PP2C-24四个基因与内休眠调控有关,而PP2C-78对于内休眠的解除则有明显作用。PP2C蛋白磷酸酶相关基因注释到植物激素信号转导途径显示,ABA受体PYR/PYL蛋白与PP2C蛋白以及SnRK2(蛋白激酶)蛋白形成ABA信号转导的复合物可以作用于转录因子ABF从而调控梨花芽的休眠。