Detection of a <Emphasis Type="Italic">SERK</Emphasis>-like gene in coconut and analysis of its expression during the formation of embryogenic callus and somatic embryos

Somatic embryogenesis involves different molecular events including differential gene expression and various signal transduction pathways. One of the genes identified in early somatic embryogenesis is S OMATIC E MBRYOGENESIS R ECEPTOR-like K INASE (SERK). Cocos nucifera (L.) is one of the most recalcitrant species for in vitro regeneration, achieved so far only through somatic embryogenesis, although just a few embryos could be obtained from a single explant. In order to increase efficiency of this process we need to understand it better. Therefore, the purpose of the present work was to determine if an ortholog of the SERK gene is present in the coconut genome, isolate it and analyze its expression during somatic embryogenesis. The results showed the occurrence of a SERK ortholog referred to as CnSERK. Predicted sequence analysis showed that CnSERK encodes a SERK protein with the domains reported in the SERK proteins in other species. These domains consist of a signal peptide, a leucine zipper domain, five LRR, the Serine-Proline-Proline domain, which is a distinctive domain of the SERK proteins, a single transmembrane domain, the kinase domain with 11 subdomains and the C terminal region. Analysis of its expression showed that it could be detected in embryogenic tissues before embryo development could be observed. In contrast it was not detected or at lower levels in non-embryogenic tissues, thus suggesting that CnSERK expression is associated with induction of somatic embryogenesis and that it could be a potential marker of cells competent to form somatic embryos in coconut tissues cultured in vitro.     

Isolation and Functional Characterization of a SERK Gene from Soybean (<Emphasis Type="Italic">Glycine max</Emphasis> (L.) Merr.)

It is well accepted that somatic embryogenesis serves a primary role in plant regeneration. However, it is also a model system to explore the regulatory and morphogenetic events in the life of a plant. To date, a suite of genes that serve important roles in somatic embryogenesis have been isolated and identified. In the present study, a novel gene designated as GmSERK1 was isolated from soybean (Glycine max (L.) Merr). Sequence and structural analysis determined that the GmSERK1 protein, which encodes 624 amino acids, belongs to the somatic embryogenesis receptor-like kinase (SERK) gene family. GmSERK1 shared all the characteristic domains of the SERK family, including five leucine-rich repeats, one proline-rich region motif, transmembrane domain, and kinase domains. DNA gel blot analysis indicated that a single copy of the GmSERK1 gene resides in the soybean genome. The GmSERK1 tissue-specific and induced expression patterns were explored using quantitative real-time PCR. Dissimilar expression levels in various tissues under different treatments were found. In addition, transient expression experiments in onion epidermal cells indicated that the GmSERK1 protein was located on the plasma membrane. The results from this study suggested that GmSERK1, a member of the SERK gene family, exhibits a broader role in various aspects of plant development and function, in addition to its basic functions in somatic embryogenesis.     

Multiple receptor-like kinase cDNAs from liverwort Marchantia polymorpha and two charophycean green algae, Closterium ehrenbergii and Nitella axillaris: Extensive gene duplications and gene shufflings in the early evolution of streptophytes

Plant receptor-like kinases (RLKs) comprise a large family with more than several hundred members in vascular plants. The RLK family is thought to have diverged specifically in the plant kingdom, and no family member has been identified in other lineages except for animals and Plasmodium, both of which have RLK related families of small size. To know the time of divergence of RLK family members by gene duplications and domain shufflings, comprehensive isolations of RLK cDNAs were performed from a nonvascular plant, liverwort Marchantia polymorpha and two charophycean green algae, Closterium ehrenbergii, and Nitella axillaris, thought to be the closest relatives to land plants. We obtained twenty-nine, fourteen, and thirteen RLK related cDNAs from M. polymorpha, C. ehrenbergii, and N. axillaris, respectively. The amino acid sequences of these RLKs were compared with those of vascular plants, and phylogenetic trees were inferred by GAMT, a genetic algorithm-based maximum likelihood (ML) method that outputs multiple trees, together with best one. The inferred ML trees revealed ancient gene duplications generating subfamilies with different domain organizations, which occurred extensively at least before the divergence of vascular and nonvascular plants. Rather it remains possible that the extensive gene duplications occurred during the early evolution of streptophytes. Multicellular-specific somatic embryogenesis receptor kinase (SERK) involved in somatic embryogenesis was found in a unicellular alga C. ehrenbergii, suggesting the evolution of SERK by gene recruitment of a unicellular gene.     

铁皮石斛体细胞胚胎发生类受体激酶基因DoSERK的克隆和表达分析

为了解铁皮石斛(Dendrobium officinale)中的体细胞胚胎发生类受体激酶基因DoSERK 的功能,在转录组测序数据的基础上克隆了DoSERK 的全长cDNA。结果表明,DoSERK 与其他植物的SERK 高度同源,编码633 个氨基酸。生物信息学分析表明,DoSERK蛋白为亲水蛋白并定位于质膜,具有1 个信号肽、1 个富脯氨酸区域、1 个跨膜区、5 个富亮氨酸重复序列以及1 个保守的蛋白激酶活性结构域,属于SERK 蛋白家族成员。系统进化树分析表明,DoSERK 与同为兰科植物的文心兰(Cyrtochilum loxense)以及卡特兰(Cattleya maxima)的SERK 亲缘关系最近。组织表达分析表明,DoSERK 在铁皮石斛中广泛表达,以幼嫩小苗根部的表达量最高。这些说明DoSERK 除了可能参与铁皮石斛体胚发生过程以外,还参与其他生长发育过程。     

Cloning and Molecular Characterization of a SERK Gene Transcriptionally Induced During Somatic Embryogenesis in Ananas comosus cv. Shenwan

A somatic embryogenesis receptor-like kinase (SERK) gene, designated as AcSERK1, was isolated from pineapple (Ananas comosus cv. Shenwan). AcSERK1 shared all the characteristic domains of the SERK family, including five leucine-rich repeats, one proline-rich region motif, transmembrane domain, and kinase domains. Somatic embryogenic cultures of pineapple were established following transfer of callus cultures to Murashige and Skoog (1962) medium containing 2,4-dichlorophenoxyacetic acid. The role of AcSERK1 during establishment of somatic embryogenesis in culture was investigated. The AcSERK1 was highly expressed during embryogenic competence acquisition and global embryo formation in culture. These findings were obtained along with morphological changes in callus cultures exhibiting embryogenic potential. Overall, levels of expression of AcSERK1 were lower in nonembryogenic tissues and organs than in embryogenic callus. In situ hybridization analysis revealed that AcSERK1 expression was detected in embryogenic tissues, including single competent cells, meristematic centers wherein embryogenic structures are formed, and global embryos. These results suggested that AcSERK1 expression was associated with induction of somatic embryogenesis and that it could be used as a potential marker gene to monitor the transition of pineapple callus tissues into competent and embryogenic cells and tissues.     

Molecular characterization of a Cyrtochilum loxense Somatic Embryogenesis Receptor-like Kinase (SERK) gene expressed during somatic embryogenesis

Somatic embryogenesis is crucial for the propagation of endangered Ecuadorian orchid species, among them Cyrtochilum loxense, in view of the fact that their number in nature or in collections is quite reduced. One of the genes expressed during somatic and zygotic embryogenesis is Somatic Embryogenesis Receptor-like Kinase (SERK). Despite the development of somatic embryogenesis protocols for orchids, no SERK genes have been isolated from this family. This is the first report on the isolation of a full-length orchid SERK sequence, namely that of Cyrtochilum loxense (ClSERK). The identity of ClSERK was inferred by the presence of all domains typical of SERK proteins: a signal peptide, a leucine zipper domain, five LRRs, a serine proline-rich domain, a transmembrane domain, a kinase domain, and the C-terminal region. We have observed that the ClSERK gene is highly expressed in embryogenic calluses generated from protocorms at the time of appearance of embryonic morphological features. At later stages when embryos become well visible on calluses, ClSERK gene expression decreases. Compared to early stages of embryo formation on calluses, the expression detected in leaf tissue is far lower, thus suggesting a role of this gene during development.     

龙眼WOX家族基因鉴定及在体胚发生早期的表达分析北大核心CSCD

为探究龙眼WUSCHEL相关的同源异型盒(WUSCHEL-related homeobox,WOX)家族基因的生物学功能与表达模式,该研究基于龙眼全基因组数据库对DlWOX家族成员进行鉴定与生物信息学分析,并利用实时荧光定量PCR(qRT-PCR)技术检测验证其在龙眼体胚发生早期三个阶段以及在不同激素处理下的表达模式。结果表明:(1)共筛选出13个龙眼DlWOX家族成员,均为不稳定蛋白;亚细胞定位预测显示DlWOX定位于细胞核与细胞骨架上;进化树分析发现,DlWOX家族分为远古支、中间支和WUS(WUSCHEL基因是WOX家族中最先发现的基因)支。(2)基因结构分析发现,DlWOX内含子数在0~19个之间,其大部分的编码蛋白都含有基序motif1与motif2,部分成员含有特异的基序;DlWOX启动子顺式作用元件包含大量光与激素响应元件。(3)对DlWOX在龙眼不同组织部位及体胚发生早期的表达模式分析发现,该家族部分成员在龙眼叶片中高表达,DlWOX14.1、DlWOX14.2和DlWOX9A在胚性愈伤组织阶段(EC)高表达;qRT-PCR分析显示,大部分龙眼DlWOX家族成员响应茉莉酸甲酯(MeJA)和赤霉素(GA)的调控,除DlWOX6外,其余成员在GA与MeJA处理下均上调表达,其中DlWOX9A在GA和MEJA处理下表达量显著上调。研究发现,龙眼DlWOX9A转录组测序结果与qRT-PCR结果的表达量存在差异并且趋势也不完全相同,推测WOX家族在龙眼的整个体胚发生早期起着重要的作用,尤其是在GE阶段;龙眼DlWOX基因在进化过程中存在高度的保守性,部分DlWOX家族成员可能通过响应GA与MeJA激素在龙眼体胚发生过程中发挥作用。     

Inhibitory effect of a defensin gene from the Andean crop maca (Lepidium meyenii) against Phytophthora infestans

In this study, we report the isolation of a defensin gene, lm-def, isolated from the Andean crop 'maca' (Lepidium meyenii) with activity against the pathogen Phytophthora infestans responsible of late blight disease of the potato and tomato crops. The lm-def gene has been isolated by polymerase chain reaction (PCR) using degenerate primers corresponding to conserved regions of 13 plant defensin genes of the Brassicaceae family assuming that defensin genes are highly conserved among cruciferous species. The lm-def gene belongs to a small multigene family of at least 10 members possibly including pseudogenes as assessed by genomic hybridization and nucleotide sequence analyses. The deduced mature Lm-Def peptide is 51 amino acids in length and has 74-94% sequence identity with other plant defensins of the Brassicaceae family. The Lm-Def peptide was produced as a fusion protein using the pET-44a expression vector and purified using an immobilized metal ion affinity chromatography. The recombinant protein (NusA:Lm-Def) exhibited in vitro activity against P. infestans. The NusA:Lm-Def protein caused growth inhibition and hyphal damage at concentration not greater than 0.4 microM. In contrast, the NusA protein alone expressed and purified similarly did not show any activity against P. infestans. Therefore, these results indicate that the lm-def gene isolated from maca belong to the plant defensin family with activity against P. infestans. Its expression in potato, as a transgene, might help to control the late blight disease caused by P. infestans with the advantage of being of plant origin.     

Two SERK genes are markers of pluripotency in Cyclamen persicum Mill

The genetic basis of stem cell specification in somatic embryogenesis and organogenesis is still obscure. SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE (SERK) genes are involved in embryogenesis and organogenesis in numerous species. In vitro culture of Cyclamen persicum immature ovules provides a system for investigating stem cell formation and maintenance, because lines forming either organs or embryos or callus without organs/embryos are available for the same cultivar and plant growth regulator conditions. The present aim was to exploit this property of cyclamen cultures to understand the role of SERK(s) in stem cell formation and maintenance in somatic embryogenesis and organogenesis in vitro, in comparison with expression in planta. CpSERK1 and CpSERK2 were isolated from embryogenic callus. CpSERK1 and CpSERK2 levels by RT-PCR showed that expression is high in embryogenic, moderate in organogenic, and null in recalcitrant calli. in situ hybridizations showed that the expression of both genes started in clumps of pluripotent stem cells, from which both pre-embryogenic aggregates and organ meristemoids derived, and continued in their trans-amplifying, meristem-like, derivatives. Expression declined in organ meristemoids, in parallel with a partial loss of meristematization. In mature somatic embryos, and in shoot and root primordia, CpSERK1 and CpSERK2 were expressed in meristems, and similar patterns occurred in zygotic embryo and primary meristems in planta. The results point to SERK1 and SERK2 as markers of pluripotency in cyclamen. It is proposed that the high expression of these genes in the trans-amplifying derivatives of the stem cells maintains a pluripotent condition leading to totipotency and, consequently, somatic embryogenesis.     

Role of SERK genes in plant environmental response

In plants, cell signaling connects the environmental input to the intracellular responses in plants. Exogenous signals play an important role in cell metabolism leading to growth and defense responses. Some of these stimuli induce anatomical and physiological modifications that are generally modulated by gene expression. SERK belongs to a small family of genes that code for a transmembrane protein involved in signal transduction and that have been strongly associated with somatic embryogenesis and apomixis in a number of plant species. Recent studies corroborate its role in somatic embryogenesis and suggest a broader range of functions in plant response to biotic and abiotic stimuli. This mini-review aims to present new data on SERK and discuss its involvement in plant development as well as in response to environmental stress.Key words: SERK, fungus tolerance, environmental stress, brassinosteroids, SAR     

Characterization of VvSERK1, VvSERK2, VvSERK3 and VvL1L genes and their expression during somatic embryogenesis of grapevine (Vitis vinifera L.)

Little is known about the genes expressed during grapevine somatic embryogenesis. Both groups of Somatic Embryogenesis Receptor Kinase (SERK) and Leafy Cotyledon (LEC and L1L) genes seem to play key roles during somatic embryogenesis in various plant species. Therefore, we identified and analysed the sequences of VvSERK and VvL1L (Leafy cotyledon1-Like) genes. The deduced amino acid sequences of VvSERK1, VvSERK2 and VvSERK3 are very similar to that of registered SERK proteins, with highest homologies for the kinase domain in the C-terminal region. The amino acid sequence of VvL1L presents all the domains that are characteristic for LEC1 and L1L proteins, particularly, the 16 amino acid residues that serve as signature of the B-domain. Phylogenetic analysis distinguishes members of subclass LEC1 and subclass L1L, and VvL1L is closely related to L1L proteins. Using semi-quantitative RT-PCR, we studied gene expression of VvSERK1, VvSERK2, VvSERK3 and VvL1L in calli and somatic embryos obtained from anther culture of Vitis vinifera L. cv Chardonnay. Expression of VvSERK2 is relatively stable during in vitro culture. In contrast, VvSERK1, VvSERK3 and VvL1L are expressed more 4 to 6 weeks after transfer of the calli onto embryo induction medium, before the visible appearance of embryos on the calli as seen by environmental scanning electron microscopy. Later on (8 weeks after transfer) VvSERK1 expression is maintained in the embryogenic calli and VvSERK3 in the embryos, whereas VvL1L expression is very low. All together, these data suggest the involvement of VvSERK and VvL1L genes in grapevine somatic embryogenesis. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Paul Schellenbaum and Alban Jacques contributed equally to this work.     

Cotton GhBAK1 Mediates Verticillium Wilt Resistance and Cell Death

Virus-induced gene silencing (VIGS) offers a powerful approach for functional analysis of individual genes by knocking down their expression. We have adopted this approach to dissect gene functions in cotton resistant to Verticillium wilt, one of the most devastating diseases worldwide. We showed here that highly efficient VIGS was obtained in a cotton breeding line (CA4002) with partial resistance to Verticillium wilt, and GhMKK2 and GhVe1 are required for its resistance to Verticillium wilt. Arabidopsis AtBAK1/SERK3, a central regulator in plant disease resistance, belongs to a subfamily of somatic embryogenesis receptor kinases (SERKs) with five members, AtSERK1 to AtSERK5. Two BAK1 orthologs and one SERK1 ortholog were identified in the cotton genome. Importantly, GhBAK1 is required for CA4002 resistance to Verticillium wilt. Surprisingly, silencing of GhBAK1 is sufficient to trigger cell death accompanied with production of reactive oxygen species in cotton. This result is distinct from Arabidopsis in which AtBAK1 and AtSERK4 play redundant functions in cell death control. Apparently, cotton has only evolved SERK1 and BAK1 whereas AtSERK4/5 are newly evolved genes in Arabidopsis. Our studies indicate the functional importance of BAK1 in Verticillium wilt resistance and suggest the dynamic evolution of SERK family members in different plant species.     

Expression of the BnmNAP subfamily of napin genes coincides with the induction of Brassica microspore embryogenesis

Brassica napus cv. Topas microspores can be diverted from pollen development toward haploid embryo formation in culture by subjecting them to a heat stress treatment. We show that this switch in developmental pathways is accompanied by the induction of high levels of napin seed storage protein gene expression. Changes in the plant growth or microspore culture conditions were not by themselves sufficient to induce napin gene expression. Specific members of the napin multigene family were cloned from a cDNA library prepared from microspores that had been induced to undergo embryogenesis. The majority of napin clones represented three members (BnmNAP2, BnmNAP3 and BnmNAP4) that, along with a previously isolated napin genomic clone (BngNAP1), constitute the highly conserved BnmNAP subfamily of napin genes. Both RNA gel blot analysis, using a subfamily-specific probe, and histochemical analysis of transgenic plants expressing a BngNAP1 promoter--glucuronidase gene fusion demonstrated that the BnmNAP subfamily is expressed in embryogenic microspores as well as during subsequent stages of microsporic embryo development.