Soybean AP1 homologs control flowering time and plant height

Flowering time and plant height are key agronomic traits that directly affect soybean (Glycine max) yield. APETALA1 (AP1) functions as a class A gene in the ABCE model for floral organ development, helping to specify carpel, stamen, petal, and sepal identities. There are four AP1 homologs in soybean, all of which are mainly expressed in the shoot apex. Here, we used clustered regularly interspaced short palindromic repeats (CRISPR) – CRISPR‐associated protein 9 technology to generate a homozygous quadruple mutant, gmap1, with loss‐of‐function mutations in all four GmAP1 genes. Under short‐day (SD) conditions, the gmap1 quadruple mutant exhibited delayed flowering, changes in flower morphology, and increased node number and internode length, resulting in plants that were taller than the wild type. Conversely, overexpression of GmAP1a resulted in early flowering and reduced plant height compared to the wild type under SD conditions. The gmap1 mutant and the overexpression lines also exhibited altered expression of several genes related to flowering and gibberellic acid metabolism, thereby providing insight into the role of GmAP1 in the regulatory networks controlling flowering time and plant height in soybean. Increased node number is the trait with the most promise for enhancing soybean pod number and grain yield. Therefore, the mutant alleles of the four AP1 homologs described here will be invaluable for molecular breeding of improved soybean yield.     

Dt2 Is a Gain-of-Function MADS-Domain Factor Gene That Specifies Semideterminacy in Soybean

Similar to Arabidopsis thaliana, the wild soybeans (Glycine soja) and many cultivars exhibit indeterminate stem growth specified by the shoot identity gene Dt1, the functional counterpart of Arabidopsis TERMINAL FLOWER1 (TFL1). Mutations in TFL1 and Dt1 both result in the shoot apical meristem (SAM) switching from vegetative to reproductive state to initiate terminal flowering and thus produce determinate stems. A second soybean gene (Dt2) regulating stem growth was identified, which, in the presence of Dt1, produces semideterminate plants with terminal racemes similar to those observed in determinate plants. Here, we report positional cloning and characterization of Dt2, a dominant MADS domain factor gene classified into the APETALA1/SQUAMOSA (AP1/SQUA) subfamily that includes floral meristem (FM) identity genes AP1, FUL, and CAL in Arabidopsis. Unlike AP1, whose expression is limited to FMs in which the expression of TFL1 is repressed, Dt2 appears to repress the expression of Dt1 in the SAMs to promote early conversion of the SAMs into reproductive inflorescences. Given that Dt2 is not the gene most closely related to AP1 and that semideterminacy is rarely seen in wild soybeans, Dt2 appears to be a recent gain-of-function mutation, which has modified the genetic pathways determining the stem growth habit in soybean.     

大豆向热带地区发展的遗传基础

大豆(Glycine max)是光周期敏感的植物,该特性是决定其生育期及其生态适应区的关键因素。温带的大豆品种引种到热带地区(短日照)时,开花期和成熟期提前、产量降低,限制了大豆在热带地区的种植。长童期(LJ)大豆品种的发现是解决该问题的重要突破。在短日照条件下,LJ品种比温带品种开花晚、体量大、成熟晚且产量提高。前期研究发现,J位点是控制LJ性状的关键位点。近期,我国科学家通过精细定位克隆了J基因,发现其与拟南芥(Arabidopsis thaliana)早花基因(ELF3)同源。他们通过功能互补和近等基因系等方法验证了J基因的功能,在短日照条件下,等位基因j比J开花晚、成熟晚且产量提高。进一步研究发现,J蛋白与E1基因(豆科植物开花抑制因子)的启动子结合抑制E1基因的表达,从而解除E1对大豆开花基因(FT)的抑制,促进大豆在短日照下开花。研究还发现在大豆种质资源中存在多种j等位变异。该研究引领了大豆生育期遗传研究的新方向,揭示了大豆向热带地区发展的遗传基础。     

The alleles at the E1 locus impact the expression pattern of two soybean FT-like genes shown to induce flowering in Arabidopsis

A small gene family of phosphatidyl ethanolamine-binding proteins (PEBP) has been shown to function as key regulators in flowering; in Arabidopsis thaliana the FT protein promotes flowering whilst the closely related TFL1 protein represses flowering. Control of flowering time in soybean [Glycine max (L.) Merrill] is important for geographic adaptation and maximizing yield. Soybean breeders have identified a series of loci, the E-genes, that control photoperiod-mediated flowering time, yet how these loci control flowering is poorly understood. The objectives of this study were to evaluate the expression of GmFT-like genes in the E1 near-isogenic line (NIL) background. Of the 20 closely related PEBP proteins in the soybean genome, ten are similar to the Arabidopsis FT protein. Expression analysis of these ten GmFT-like genes confirmed that only two are detectable in the conditions tested. Further analysis of these two genes in the E1 NILs grown under short-day (SD) and long-day (LD) conditions showed a diurnal expression and tissue specificity expression commensurate with soybean flowering time under SD and LD conditions, suggesting that these were good candidates for flowering induction in soybean. Arabidopsis ft mutant lines flowered early when transformed with the two soybean genes, suggesting that the soybean genes can complement the Arabidopsis FT function. Flowering time in E1 NILs is consistent with the differential expression of the two GmFT-like genes under SD and LD conditions, suggesting that the E1 locus, at least in part, impacts time to flowering through the regulation of soybean FT expression.     

FLC调控植物成花的分子机制研究新进展

FLC是植物成花关键抑制因子, 主要通过结合到其下游2个关键的成花促进基因(FT和SOC1)启动子上而抑制二者的表达。此外, 还可以与其它调控因子结合调控开花。然而, 关于FLC在成花调控中的具体分子机制仍需深入研究。该文主要结合8条成花调控遗传途径, 梳理近年来与FLC相关的新进展, 并展望了未来的研究方向。     

陆地棉GST基因家族全基因组分析

谷胱甘肽转移酶(glutathione-S-transferase, GST)是一种普遍存在的具有多功能的超家族蛋白,在植物初次生代谢、逆境胁迫、胞间信号传递等方面具有重要作用;同时,作为配体其在植物激素代谢以及物质转运方面也发挥作用。为了解析陆地棉(Gossypium hirsutum L.) GST基因家族的信息,本研究对该基因家族成员的种类、进化关系、物理定位、基因结构和保守基序以及表达模式进行了分析。结果显示,在陆地棉全基因组中共含有70个GST基因,进化树和基因结构分析将该家族分为U族、F族、T族、Z族、EF1Bγ族和TCHQD族。基因定位分析发现,除了AD/At2、AD/At4、AD/At5、AD/Dt5、AD/Dt10号染色体上没有GST基因外,其他染色体上都有GST基因,并且在AD/At9、AD/Dt7、AD/Dt12、AD/Dt13这4条染色体上出现基因簇。对F族(Phi类) 9个GST基因进行荧光定量分析,结果表明,除GhGSTF1可能为假基因外,GhGSTF2~9等8个基因在陆地棉根、茎、叶以及各个发育时期的纤维中均有表达;结合生物信息学分析,推测GhGSTF8可能参与原花青素/花青素的转运和积累;GhGSTF4、GhGSTF6和GhGSTF9可能在调节陆地棉的生长和胁迫反应中起作用,而GhGSTF2、GhGSTF3、GhGSTF5和GhGSTF7的功能还有待进一步研究。本研究为陆地棉GST基因家族的分子进化及功能研究提供了理论依据。     

A recent retrotransposon insertion of J caused E6 locus facilitating soybean adaptation into low latitude

Soybean (Glycine max) is an important legume crop that was domesticated in temperate regions. Soybean varieties from these regions generally mature early and exhibit extremely low yield when grown under inductive short-day (SD) conditions at low latitudes. The long-juvenile (LJ) trait, which is characterized by delayed flowering and maturity, and improved yield under SD conditions, allowed the cultivation of soybean to expand to lower latitudes. Two major loci control the LJ trait: J and E6. In the current study, positional cloning, sequence analysis, and transgenic complementation confirmed that E6 is a novel allele of J, the ortholog of Arabidopsis thaliana EARLY FLOWERING 3 (ELF3). The mutant allele e6^PG, which carries a Ty1/Copia-like retrotransposon insertion, does not suppress the legume-specific flowering repressor E1, allowing E1 to inhibit Flowering Locus T (FT) expression and thus delaying flowering and increasing yields under SD conditions. The e6^PG allele is a rare allele that has not been incorporated into modern breeding programs. The dysfunction of J might have greatly facilitated the adaptation of soybean to low latitudes. Our findings increase our understanding of the molecular mechanisms underlying the LJ trait and provide valuable resources for soybean breeding.     

RID1 sets rice heading date by balancing its binding with SLR1 and SDG722

Rice (Oryza sativa) is a major crop that feeds billions of people, and its yield is strongly influenced by flowering time (heading date). Loss of RICE INDETERMINATE1 (RID1) function causes plants not to flower; thus, RID1 is considered a master switch among flowering-related genes. However, it remains unclear whether other proteins function together with RID1 to regulate rice floral transition. Here, we revealed that the chromatin accessibility and H3K9ac, H3K4me3, and H3K36me3 levels at Heading date 3a (Hd3a) and RICE FLOWERING LOCUS T1 (RFT1) loci were significantly reduced in rid1 mutants. Notably, RID1 interacted with SET DOMAIN GROUP PROTEIN 722 (SDG722), a methyltransferase. We determined that SDG722 affects the global level of H3K4me2/3 and H3K36me2/3, and promotes flowering primarily through the Early heading date1-Hd3a/RFT1 pathway. We further established that rice DELLA protein SLENDER RICE1 (SLR1) interacted with RID1 to inhibit its transactivation activity, that SLR1 suppresses rice flowering, and that messenger RNA and protein levels of SLR1 gradually decrease with plant growth. Furthermore, SLR1 competed with SDG722 for interaction with RID1. Overall, our results establish that interplay between RID1, SLR1, and SDG722 feeds into rice flowering-time control.     

Terminal flower2, an Arabidopsis homolog of heterochromatin protein1, counteracts the activation of flowering locus T by constans in the vascular tissues of leaves to regulate flowering time

The flowering time of plants is tightly regulated by both promotive and repressive factors. Molecular genetic studies using Arabidopsis have identified several epigenetic repressors that regulate flowering time. Terminal flower2, (TFL2), which encodes a homolog of heterochromatin protein1 represses flowering locus T (FT) expression, which is induced by the activator constans (CO) in response to the long-day signal. Here, we show that TFL2, CO, and FT are expressed together in leaf vascular tissues and that TFL2 represses FT expression continuously throughout development. Mutations in TFL2 derepress FT expression within the vascular tissues of leaves, resulting in daylength-independent early flowering. TFL2 can reduce FT expression even when CO is overexpressed. However, FT expression reaches a level sufficient for floral induction even in the presence of TFL2, suggesting that TFL2 does not maintain FT in a silent state or inhibit it completely; rather, it counteracts the effect of CO on FT activation.     

两株链霉菌对非洲菊生长和生理生化指标的影响

本研究以非洲菊(Gerbera jamesonii)为试材,采用不同浓度的脱叶链霉菌FT05W和深蓝链霉菌ZEA17I孢子悬浮液浇灌盆栽非洲菊,筛选出非洲菊的最佳施用浓度,探索两株链霉菌对非洲菊生长和生理生化指标的影响,为非洲菊生产上科学合理施用链霉菌提供理论依据。结果表明: 脱叶链霉菌FT05W和深蓝链霉菌ZEA17I不同浓度孢子悬浮液均能有效促进非洲菊的生长,前者对非洲菊的作用效果优于后者,以浓度为1×10⁹ CFU·mL^-1的脱叶链霉菌FT05W效果最好。与蒸馏水对照相比,该处理显著促进了非洲菊株高(30.2%)和冠幅(41.5%)的生长,并在一定程度上促进了花茎的增长和增粗;能显著提高非洲菊植株叶片的叶绿素含量(65.2%)、根系活力(103.3%)和超氧化物歧化酶活性(84.4%),使丙二醛含量维持在较低的水平。因此在一定的浓度范围内,脱叶链霉菌FT05W和深蓝链霉菌ZEA17I均能有效促进非洲菊的生长,有利于非洲菊植株体内同化物的转运和积累,增强非洲菊植株抗逆性,特别是脱叶链霉菌FT05W具有在未来作为生物肥料解决非洲菊连作障碍的应用潜力。     

miR172-AP2模块调控植物生长发育及逆境响应的研究进展

MicroRNA (miRNA)是一类具有调控能力的非编码小分子RNA, 通过与靶基因mRNA特异或非特异性结合, 诱导靶基因mRNA降解或抑制其翻译, 从而调控植物的生长发育。其中, miR172的靶基因AP2所编码的转录因子为植物所特有, miR172在转录后或翻译水平对AP2进行表达调控, 进而调控植物的花发育、时序转换、小穗形态、块茎和果实发育、结瘤(豆科)以及逆境响应等过程。该文综述了近年来miR172-AP2模块在植物生长发育调控方面的最新研究进展。     

Evidence for the involvement of jasmonic acid in the control of the stem-growth habit of soybean plants

Soybean plants show diversity in stem-growth habit which ranges from the determinate type to the indeterminate type. Stem growth of determinate plants abruptly terminate near the beginning of flowering. The possible involvement of jasmonic acid (JA) in the control of the stem growth-habit was examined in indeterminate and determinate isolines of soybean [ Glycine max (L.) Merril cv. Harosoy]. JA-like activities in leaves of both isolines were very low 20 days before the commencement of flowering. The activity increased rapidly thereafter and reached a maximum near the time of flowering. Although the activities in leaves of both isolines fluctuated in a similar manner, the activity in the determinate isoline was much higher than that in the indeterminate isoline after flowering. The presence of JA in the leaves of the determinate isoline was confirmed by purification by high-performance liquid chromatography and by mass spectrometry. Exogenous application of JA to cultured shoot apices of the indeterminate isoline strongly inhibited growth. These results suggest that jasmonic acid is a major endogenous factor that controls the growth habit of soybean plants.