Selection-Driven Divergence After Gene Duplication in Arabidopsis thaliana

Gene duplications are one of the most important mechanisms for the origin of evolutionary novelties. Even though various models of the fate of duplicated genes have been established, current knowledge about the role of divergent selection after gene duplication is rather limited. In this study, we analyzed sequence divergence in response to neo- and subfunctionalization of segmentally duplicated genes in the genome of Arabidopsis thaliana. We compared the genomes of A. thaliana and the poplar Populus trichocarpa to identify orthologous pairs of genes and their corresponding inparalogs. Maximum-likelihood analyses of the nonsynonymous and synonymous substitution rate ratio [Formula: see text] of pairs of A. thaliana inparalogs were used to detect differences in the evolutionary rates of protein coding sequences. We analyzed 1,924 A. thaliana paralogous pairs and our results indicate that around 6.9% show divergent ω values between the lineages for a fraction of sites. We observe an enrichment of regulatory sequences, a reduced level of co-expression and an increased number of substitutions that can be attributed to positive selection based on an McDonald-Kreitman type of analysis. Taken together, these results show that selection after duplication contributes substantially to gene novelties and hence functional divergence in plants.     

Asymmetric Divergence in Structure and Function of HCN Channel Duplicates in Ciona intestinalis

Hyperpolarization-activated Cyclic Nucleotide (HCN) channels are voltage-gated cation channels and are critical for regulation of membrane potential in electrically active cells. To understand the evolution of these channels at the molecular level, we cloned and examined two of three HCN homologs of the urochordate Ciona intestinalis (ciHCNa and ciHCNb). ciHCNa is like mammalian HCNs in that it possesses similar electrical function and undergoes N-glycosylation of a sequon near the pore. ciHCNb lacks the pore-associated N-glycosylation sequon and is predictably not N-glycosylated, and it also has an unusual gating phenotype in which the channel''s voltage-sensitive gate appears to close incompletely. Together with previous findings, the data support an evolutionary trajectory in which an HCN ancestor underwent lineage-specific duplication in Ciona, to yield one HCN with most features that are conserved with the mammalian HCNs and another HCN that has been uniquely altered.     

Functional bioinformatics for Arabidopsis thaliana

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Functional bioinformatics for Arabidopsis thaliana

MOTIVATION: The genome of Arabidopsis thaliana, which has the best understood plant genome, still has approximately one-third of its genes with no functional annotation at all from either MIPS or TAIR. We have applied our Data Mining Prediction (DMP) method to the problem of predicting the functional classes of these protein sequences. This method is based on using a hybrid machine-learning/data-mining method to identify patterns in the bioinformatic data about sequences that are predictive of function. We use data about sequence, predicted secondary structure, predicted structural domain, InterPro patterns, sequence similarity profile and expressions data. RESULTS: We predicted the functional class of a high percentage of the Arabidopsis genes with currently unknown function. These predictions are interpretable and have good test accuracies. We describe in detail seven of the rules produced.     

拟南芥LecRK-ConA基因突变体的筛选鉴定及其功能初步研究

植物凝集素类受体激酶(lectin receptor-like kinases,LecRLKs)在植物抗逆性、激素信号转导及生长发育调节等方面扮演重要角色。LecRK-ConA基因是拟南芥Lec RLK基因家族中的一员。利用三引物法鉴定获得LecRK-ConA基因两个缺失突变体的纯合子。启动子顺式作用元件分析显示,LecRK-ConA具有多个与干旱、光、赤霉素(gibberellic acid,GA)等应答相关的元件。实时定量PCR结果表明:LecRK-ConA基因具有组织表达差异性,且在春化后4 d的种子中表达量最强,用NaCl和甘露醇处理均能抑制该基因的表达。用NaCl和甘露醇处理缺失突变体lecrk-cona和Col-0后,发现lecrk-cona的种子萌发率显著低于野生型。此外,突变体lecrkcona相对野生型Col-0来说,具有早花现象。上述实验结果为进一步深入研究LecRK-ConA基因在抗逆与开花调控途径中的生理功能奠定了基础。     

Robust Self-Incompatibility in the Absence of a Functional ARC1 Gene in Arabidopsis thaliana

Self-incompatibility (SI) is the primary determinant of the outbreeding mode of sexual reproduction in the Brassicaceae. All Arabidopsis thaliana accessions analyzed to date carry mutations that disrupt SI functions by inactivating the SI specificity-determining S locus or SI modifier loci. S-locus genes isolated from self-incompatible close relatives of A. thaliana restore robust SI in several accessions that harbor only S-locus mutations and confer transient SI in accessions that additionally harbor mutations at modifier loci. Self-incompatible transgenic A. thaliana plants have proved to be valuable for analysis of the recognition and signaling events that underlie SI in the Brassicaceae. Here, we review results demonstrating that S-locus genes are necessary and sufficient for SI signaling and for restoration of a strong and developmentally stable SI phenotype in several accessions of A. thaliana. The data indicate that introduction of a functional E3 ligase-encoding ARC1 gene, which is deleted in all accessions that have been analyzed to date, is not required for SI signaling leading to inhibition of self pollen or for reversion of A. thaliana to its fully self-incompatible ancestral state.It is well established that specific pollen recognition in the self-incompatibility (SI) response of the Brassicaceae is determined by allele-specific interactions that occur at the stigma surface between two highly polymorphic proteins encoded in the S locus: the S-locus receptor kinase SRK and its ligand, the S-locus cysteine-rich protein SCR. Arabidopsis thaliana lacks a functional SI system and harbors nonfunctional S-locus variants that contain defective alleles of the SRK and/or SCR genes (Kusaba et al., 2001; Sherman-Broyles et al., 2007; Tang et al., 2007; Shimizu et al., 2008; Boggs et al., 2009a; Tsuchimatsu et al., 2010; Dwyer et al., 2013). Despite being highly self-fertile, A. thaliana can be made to express SI upon transformation with functional SRK-SCR gene pairs isolated from its self-incompatible close relatives (Nasrallah et al., 2002, 2004; Boggs et al., 2009a, 2009b). The first transfer of the SI trait into A. thaliana was achieved using the SRKb-SCRb gene pair isolated from the Sb locus of Arabidopsis lyrata (Kusaba et al., 2001; Nasrallah et al., 2002, 2004). Many of the subsequent studies that have been performed in the transgenic A. thaliana SRK-SCR system have used plants transformed with p548, a plasmid that we constructed by inserting the A. lyrata SRKb and SCRb genes with their 5′ and 3′ regulatory sequences into the pBIN+ binary vector (Nasrallah et al., 2004).Indriolo et al. (2014) recently used the p548 plasmid to generate SRKb-SCRb transformants and test the role of the ARM Repeat Containing1 (ARC1) gene in SI. ARC1 was originally identified as a Brassica napus protein that interacts with the SRK kinase domain in yeast (Gu et al., 1998), and it was subsequently inferred to be required for SI because downregulation of the ARC1 gene in B. napus (Stone et al., 1999) and A. lyrata (Indriolo et al., 2012), as well as overexpression of ARC1’s target, Exo70A1, in B. napus (Samuel et al., 2009), caused partial breakdown of the SI response. However, the involvement of the proposed SRK-ARC1-Exo70A1 pathway in SI has been questioned because the ARC1 gene was found to be deleted in all A. thaliana accessions analyzed to date (Kitashiba et al., 2011; Indriolo et al., 2012), including those in which the SRKb-SCRb transgenes confer a strong SI phenotype (Kitashiba et al., 2011). Additionally, overexpression of Exo70A1 did not cause weakening of the SI response in A. thaliana SRKb-SCRb plants (Kitashiba et al., 2011).Indriolo et al. (2014) reported on their characterization of the SI response in plants of the Sha and Columbia-0 (Col-0) accessions, which they either transformed with the p548 plasmid alone or cotransformed with p548 and a plasmid containing an ARC1 gene isolated from A. lyrata or B. napus. They concluded that, along with SRK and SCR, “ARC1 is the third component that is required to return A. thaliana to its ancestral self-incompatibility state.” However, this conclusion is inconsistent with results of previous studies of SI in transgenic A. thaliana SRK-SCR transformants, which have shown that several A. thaliana accessions are rendered fully self-incompatible by transformation with the p548 plasmid without the addition of a functional ARC1 gene. Contrary to Indriolo et al.’s assertion that in previous studies of A. thaliana SRK-SCR transformants, “the self-pollen rejection response was incomplete,” we reported that among 11 A. thaliana accessions tested by transformation with the p548 plasmid, five accessions (C24, Cvi-0, Hodja, Kas-2, and Sha) were converted to full SI by expression of the SRKb and SCRb genes alone (Nasrallah et al., 2004; Boggs et al., 2009a). Importantly, the SI phenotype of these self-incompatible SRKb-SCRb transformants faithfully recapitulates the SI phenotype of naturally self-incompatible Brassicaceae with respect to the four defining features of SI in this family: (1) site of pollen inhibition at the stigma surface, (2) intensity of the response, (3) developmental regulation over the course of stigma maturation, and (4) heritability. These features suggest that the inhibition of self pollen in self-incompatible A. thaliana SRK-SCR transformants is achieved via the same signaling pathway as that utilized by other self-incompatible Brassicaceae species.     

Gene targeting in Arabidopsis thaliana.

Summary Gene targeting of a chromosomally integrated transgene in Arabidopsis thaliana is reported. A chimeric gene consisting of the promoter of the 35S RNA of CaMV, the polyadenylation signal of the octopine synthase gene and the coding region of the bacterial hygromycin phosphotransferase gene (hpt), which was rendered non-functional by deletion of 19 bp, was introduced into the genome of A. thaliana using Agrobacterium-mediated gene transfer. A total of 3.46 x 10⁸ protoplasts isolated from 17 independent transgenic Arabidopsis lines harbouring the defective chimeric hpt gene were transformed via direct gene transfer using various DNA forms containing only the intact coding region of the hpt gene. Out of 150 hygromycin-resistant colonies appearing in the course of these experiments, four were the result of targeted recombination of the incoming DNA with the defective chromosomal locus as revealed by PCR and Southern blot analysis. Comparison with the number of transformants obtained when an hpt gene controlled by a promoter and terminator from the nopaline synthase gene was employed results in a maximal ratio of homologous to non-homologous transformation in A. thaliana of 1 x 10^–4.     

拟南芥亚硫酸盐氧化酶基因AtSO启动子的分离与功能分析

亚硫酸盐氧化酶(SO)作为目前发现的钼酶家族成员之一,在哺乳动物硫化物的脱毒、嘌呤代谢等过程中起着非常重要的作用。然而,很少有关于高等植物SO的表达和调控机制的研究报道。本研究中,我们用半定量RT-PCR和组织化学方法对拟南芥中SO基因AtSO的表达调控进行了初步研究。结果表明,AtSO在拟南芥的地上部分如茎、叶、花和未成熟荚果中有较高的表达水平,而在根部表达水平较低。在对分离的该基因上游1562-bp的启动子区域进行生物信息学分析时,鉴定出一些可能的调控元件如光调控元件(LRE)。转基因植株中AtSO启动子驱动下的GUS基因(uidA)表达结果表明:AtSO的表达主要在植物的地上组织,表达具有光依赖性,且表达水平受亚硫酸盐的诱导增高。这一结果对进一步研究SO在植物对光周期和亚硫酸盐胁迫应答反应中的作用提供线索。     

拟南芥Rab1家族基因的克隆和功能研究

Yptl蛋白是酵母唯一的Rab1 GTP酶,调控囊泡从内质网到高尔基体的运输.酵母温敏突变株 ASY01是一个Ypt1基因功能部分缺失菌株,在26℃可以正常生长,但在37℃不能生长.拟南芥有4个Rab1基因,分别是AtRab1A1、AtRab1B1、AtRab1B2、AtRab1C1.克隆了所有4个AtRab1基因,构建酵母表达载体,转化温敏突变型酵母ASY01.温度敏感性实验结果表明,所有转基因菌株在37℃都恢复正常生长.说明拟南芥4个Rab1基因都与酵母Ypt1基因功能互补,都具有调节囊泡从内质网到高尔基体运输的功能.     

拟南芥ABC转运类蛋白家族的分子进化、表达模式和蛋白功能网络预测分析

ABC转运蛋白又称腺苷三磷酸结合盒转运蛋白(ATP-binding cassette transporters),该基因家族是目前已知最大、最古老的蛋白家族之一,在植物中ABC转运蛋白种类繁多、结构复杂、功能多样,涉及植物一切的生命活动过程。本研究系统介绍了拟南芥中131个ABC转运蛋白的亚家族分类、系统命名、蛋白大小以及蛋白亚细胞定位等基因信息,在此基础上,分析了ABC转运蛋白基因在染色体分布以及进化过程中发生的复制事件;其次在47个组织器官或发育阶段中聚类分析了ABC转运蛋白的表达模式和各个亚家族分布规律,结果表明ABC转运蛋白基因的表达具有明显的组织特异性和时空特异性,说明在进化过程中该类蛋白功能也进一步发生分化;我们以花药发育过程为例,说明ABC转运蛋白在花药发育过程中具有较高的协调性,在时空和组织上表达受到严格的调控;最后我们分析了ABC转运蛋白亚家族内部和各个亚家族之间可能存在的蛋白相互作用关系,推测ABC半分子转运蛋白形成同源或异源二聚体发挥功能的可能性,进一步说明ABC转运蛋白在蛋白互作水平上也存在功能多样性和严格的调控关系。     

Herbicide Safener-Inducible Gene Expression in Arabidopsis thaliana

The potential use of a new chemical-inducibie gene expressionsystem in Arabidopsis thaliana has been examined. The systemis based on the maize In2-2 promoter which is activated by benzenesulfonamideherbicide safe-ners. Plants transformed with the ß-glucuronidase(gus) reporter gene under the control of the In2-2 promoterwere grown in the presence of different safeners and the inducedGUS activity pattern was studied histochemically. In the absenceof safeners, the In2-2 promoter was not active. Applicationof different safeners induced distinct gus expression patterns,including expression in the root, hy-dathodes, and the shootapical meristem. Plants maintained continuously on inducingconcentrations of the safeners were retarded in growth. Thegrowth inhibition effects of the Sa5 safener could be overcomein a sul-fonylurea-resistant background. In2-2 promoter activitycould also be induced by the sulfonylurea herbicide chlor-sulfuron.In the sulfonylurea-resistant background, which derives fromherbicide-resistant acetolactate synthase activity, inductionof the In2-2 promoter by chlorsulfuron was lower. Furthermore,branched-chain amino acids, known to inhibit acetolactate synthaseactivity, also induced In2-2 promoter activity. Our data suggesta strong correlation between In2-2 expression and inhibitionof the acetolactate synthase activity. (Received November 12, 1996; Accepted February 21, 1997)     

Gene action of new mutations in Arabidopsis thaliana

For a newly arising mutation affecting a trait under selection, its degree of dominance relative to the preexisting allele(s) strongly influences its evolutionary impact. We have estimated dominance parameters for spontaneous mutations in a subset of lines derived from a highly inbred founder of Arabidopsis thaliana by at least 17 generations of mutation accumulation (MA). The labor-intensive nature of the crosses and the anticipated subtlety of effects limited the number of MA lines included in this study to 8. Each MA line was selfed and reciprocally crossed to plants representing the founder genotype, and progeny were assayed in the greenhouse. Significant mutational effects on reproductive fitness included a recessive fitness-enhancing effect in one line and fitness-reducing effects, one additive and the other slightly recessive. Mutations conferring earlier phenology or smaller leaves were significantly recessive. For effects increasing leaf number and reducing height at flowering, additive gene action accounted for the expression of the traits. The sole example of a significantly dominant mutational effect delayed phenology. Our findings of recessive action of a fitness-enhancing mutational effect and additive action of a deleterious effect counter a common expectation of (partial) dominance of alleles that increase fitness, but the frequency of occurrence of such mutations is unknown.     

Gene prediction and gene classes in Arabidopsis thaliana

Gene prediction methods for eukaryotic genomes still are not fully satisfying. One way to improve gene prediction accuracy, proven to be relevant for prokaryotes, is to consider more than one model of genes. Thus, we used our classification of Arabidopsis thaliana genes in two classes (CU(1) and CU(2)), previously delineated according to statistical features, in the GeneMark gene identification program. For each gene class, as well as for the two classes combined, a Markov model was developed (respectively, GM-CU(1), GM-CU(2) and GM-all) and then used on a test set of 168 genes to compare their respective efficiency. We concluded from this analysis that GM-CU(1) is more sensitive than GM-CU(2) which seems to be more specific to a gene type. Besides, GM-all does not give better results than GM-CU(1) and combining results from GM-CU(1) and GM-CU(2) greatly improve prediction efficiency in comparison with predictions made with GM-all only. Thus, this work confirms the necessity to consider more than one gene model for gene prediction in eukaryotic genomes, and to look for gene classes in order to build these models.