Embryo defective 14 encodes a plastid‐targeted cGTPase essential for embryogenesis in maize

The embryo defective (emb) mutants in maize genetically define a unique class of loci that is required for embryogenesis but not endosperm development, allowing dissection of two developmental processes of seed formation. Through characterization of the emb14 mutant, we report here that Emb14 gene encodes a circular permuted, YqeH class GTPase protein that likely functions in 30S ribosome formation in plastids. Loss of Emb14 function in the null mutant arrests embryogenesis at the early transition stage. Emb14 was cloned by transposon tagging and was confirmed by analysis of four alleles. Subcellular localization indicated that the EMB14 is targeted to chloroplasts. Recombinant EMB14 is shown to hydrolyze GTP in vitro (K_m = 2.42 ± 0.3 μm ). Emb14 was constitutively expressed in all tissues examined and high level of expression was found in transition stage embryos. Comparison of emb14 and WT indicated that loss of EMB14 function severely impairs accumulation of 16S rRNA and several plastid encoded ribosomal genes. We show that an EMB14 transgene complements the pale green, slow growth phenotype conditioned by mutations in AtNOA1, a closely related YqeH GTPase of Arabidopsis. Taken together, we propose that the EMB14/AtNOA1/YqeH class GTPases function in assembly of the 30S subunit of the chloroplast ribosome, and that this function is essential to embryogenesis in plants.     

Emb15 encodes a plastid ribosomal assembly factor essential for embryogenesis in maize

Ribosome assembly factors guide the complex process by which ribosomal proteins and the ribosomal RNAs form a functional ribosome. However, the assembly of plant plastid ribosomes is poorly understood. In the present study, we discovered a maize (Zea mays) plastid ribosome assembly factor based on our characterization of the embryo defective 15 (emb15) mutant. Loss of function of Emb15 retards embryo development at an early stage, but does not substantially affect the endosperm, and causes an albino phenotype in other genetic backgrounds. EMB15 localizes to plastids and possesses a ribosome maturation factor M (RimM) domain in the N-terminus and a predicted UDP-GlcNAc pyrophosphorylase domain in the C-terminus. The EMB15 RimM domain originated in bacteria and the UDP-GlcNAc pyrophosphorylase domain originated in fungi; these two domains came together in the ancestor of land plants during evolution. The N-terminus of EMB15 complemented the growth defect of an Escherichia coli strain with a RimM deletion and rescued the albino phenotype of emb15 homozygous mutants. The RimM domain mediates the interaction between EMB15 and the plastid ribosomal protein PRPS19. Plastid 16S rRNA maturation is also significantly impaired in emb15. These observations suggest that EMB15 functions in maize seed development as a plastid ribosome assembly factor, and the C-terminal domain is not important under normal conditions.     

The Requirement of WHIRLY1 for Embryogenesis Is Dependent on Genetic Background in Maize

Plastid gene expression is essential to embryogenesis in higher plants, but the underlying mechanism is obscure. Through molecular characterization of an embryo defective 16 (emb16) locus, here we report that the requirement of plastid translation for embryogenesis is dependent on the genetic background in maize (Zea mays). The emb16 mutation arrests embryogenesis at transition stage and allows the endosperm to develop largely normally. Molecular cloning reveals that Emb16 encodes WHIRLY1 (WHY1), a DNA/RNA binding protein that is required for genome stability and ribosome formation in plastids. Interestingly, the previous why1 mutant alleles (why1-1 and why1-2) do not affect embryogenesis, only conditions albino seedlings. The emb16 allele of why1 mutation is in the W22 genetic background. Crosses between emb16 and why1-1 heterozygotes resulted in both defective embryos and albino seedlings in the F1 progeny. Introgression of the emb16 allele from W22 into A188, B73, Mo17, Oh51a and the why1-1 genetic backgrounds yielded both defective embryos and albino seedlings. Similar results were obtained with two other emb mutants (emb12 and emb14) that are impaired in plastid protein translation process. These results indicate that the requirement of plastid translation for embryogenesis is dependent on genetic backgrounds, implying a mechanism of embryo lethality suppression in maize.     

Uncovering the Post-embryonic Role of Embryo Essential Genes in Arabidopsis using the Controlled Induction of Visibly Marked Genetic Mosaics: EMB506, an Illustration

The embryo essential gene EMB506 plays a crucial role in the transition of the Arabidopsis embryo from radial symmetry to bilateral symmetry just prior to the early heart stage of development. In addition to influencing embryo development EMB506 also affects chloroplast biogenesis. To further investigate the role of EMB506 gene expression in Arabidopsis we have generated green fluorescent protein (GFP) marked emb506 mosaic sectors at temporally defined stages during embryogenesis and additionally during various stages of vegetative growth, in otherwise phenotypically wild-type plants. We confirm the essential requirement for EMB506 gene expression in chloroplast biogenesis as reflected by the decreased chlorophyll content in emb506 mosaic sectors. We also show that the influence of EMB506 gene expression as it impinges on chloroplast biogenesis is first relevant at an intermediate stage in embryogenesis and that the role of EMB506 gene expression in chloroplast biogenesis is distinct from the essential role of EMB506 gene expression during early embryo development. By inducing emb506 mosaicism after the essential requirement for EMB506 gene expression in embryogenesis and also during vegetative growth we reveal that EMB506 gene expression additionally is required for correct cotyledon-, true leaf- and cauline leaf margin development. The strategy that we describe can be tailored to the mosaic analysis of any cloned EMB gene for which a corresponding mutant exists and can be applied to the mosaic analysis of mutant lethal genes in general.     

Morphogenesis of maize embryos requires ZmPRPL35-1 encoding a plastid ribosomal protein

In emb (embryo specific) mutants of maize (Zea mays), the two fertilization products have opposite fates: Although the endosperm develops normally, the embryo shows more or less severe aberrations in its development, resulting in nonviable seed. We show here that in mutant emb8516, the development of mutant embryos deviates as soon as the transition stage from that of wild-type siblings. The basic events of pattern formation take place because mutant embryos display an apical-basal polarity and differentiate a protoderm. However, morphogenesis is strongly aberrant. Young mutant embryos are characterized by protuberances at their suspensor-like extremity, leading eventually to structures of irregular shape and variable size. The lack of a scutellum or coleoptile attest to the virtual absence of morphogenesis at the embryo proper-like extremity. Molecular cloning of the mutation was achieved based on cosegregation between the mutant phenotype and the insertion of a MuDR element. The Mu insertion is located in gene ZmPRPL35-1, likely coding for protein L35 of the large subunit of plastid ribosomes. The isolation of a second allele g2422 and the complementation of mutant emb8516 with a genomic clone of ZmPRPL35-1 confirm that a lesion in ZmPRPL35-1 causes the emb phenotype. ZmPRPL35-1 is a low-copy gene present at two loci on chromosome arms 6L and 9L. The gene is constitutively expressed in all major tissues of wild-type maize plants. Lack of expression in emb/emb endosperm shows that endosperm development does not require a functional copy of ZmPRPL35-1 and suggests a link between plastids and embryo-specific signaling events.     

Novel phenotypes and developmental arrest in early embryo specific mutants of maize

Embryo specific (emb) mutants exhibit aberrant embryo development without deleterious effects on endosperm development. We have analyzed five emb mutants of maize, which, based on their developmental profiles can be divided into two groups: mutants arrested at early stages and mutants with novel phenotypes. The members of the first group resemble wild-type proembryos and never reach other developmental stages. In the second group the tube-shaped mutants emb*-8522 and emb*-8535 completely lack apical-basal differentiation, while in mutant emb*-8516 a second embryo-like structure arises from the suspensor. The five emb mutations analyzed are non-allelic and two of the mutations are very likely caused by insertion of the transposon mutator, opening the door for their molecular analysis. Received: 10 February 1999 / Accepted: 7 July 1999     

Partial complementation of embryo defective mutations: a general strategy to elucidate gene function

The EMB 506 gene has been characterised as essential for embryo development. To provide insights into the role of EMB 506, which is hidden by the embryo defective phenotype, the ABI3 promoter was fused to the EMB 506 cDNA. The expression of such a transgene should provide sufficient protein during embryogenesis to ensure normal embryo development in homozygous emb 506 seeds. We show that homozygous emb 506 seedlings, partially complemented with the ABI3::EMB 506 transgene, can be obtained. Most of the rescued emb 506 plants are able to flower and to set normal seeds, but show mild to severe depigmentation of rosette leaves and/or inflorescences. This effect on chloroplast development indicated a putative chloroplast localisation of the EMB 506 protein, which was demonstrated by GFP-protein fusion. However, EMB 506 cannot be considered as a chloroplast housekeeping protein only, since EMB 506 is not present in all photosynthetic tissues. This study demonstrates the power of this simple strategy, which could be widely applied to other emb mutants and which may reveal similar or additional roles for EMB genes at vegetative stages of the life cycle.     

EMB1211 is required for normal embryo development and influences chloroplast biogenesis in Arabidopsis

Chloroplast biogenesis is tightly linked with embryogenesis and seedling development. A growing body of work has been done on the molecular mechanisms underlying chloroplast development; however, the molecular components involved in chloroplast biogenesis during embryogenesis remain largely uncharacterized. In this paper, we show that an Arabidopsis mutant carrying a T‐DNA insertion in a gene encoding a multiple membrane occupation and recognition nexus (MORN)‐containing protein exhibits severe defects during embryogenesis, producing abnormal embryos and thereby leading to a lethality of young seedlings. Genetic and microscopic studies reveal that the mutation is allelic to a previously designated Arabidopsis embryo‐defective 1211 mutant (emb1211). The emb1211 +/? mutant plants produce approximately 25% of white‐colored ovules with abnormal embryos since late globular stage when primary chloroplast biogenesis takes place, while the wild‐type plants produce all green ovules. Transmission electron microscopic analysis reveals the absence of normal chloroplast development, both in the mutant embryos and in the mutant seedlings, that contributes to the albinism. The EMB1211 gene is preferentially expressed in developing embryos as revealed in the EMB1211::GUS transgenic plants. Taken together, the data indicate that EMB1211 has an important role during embryogenesis and chloroplast biogenesis in Arabidopsis.     

GIANT EMBRYO encodes CYP78A13, required for proper size balance between embryo and endosperm in rice

Among angiosperms there is a high degree of variation in embryo/endosperm size in mature seeds. However, little is known about the molecular mechanism underlying size control between these neighboring tissues. Here we report the rice GIANT EMBRYO (GE) gene that is essential for controlling the size balance. The function of GE in each tissue is distinct, controlling cell size in the embryo and cell death in the endosperm. GE, which encodes CYP78A13, is predominantly expressed in the interfacing tissues of the both embryo and endosperm. GE expression is under negative feedback regulation; endogenous GE expression is upregulated in ge mutants. In contrast to the loss‐of‐function mutant with large embryo and small endosperm, GE overexpression causes a small embryo and enlarged endosperm. A complementation analysis coupled with heterofertilization showed that complementation of ge mutation in either embryo or endosperm failed to restore the wild‐type embryo/endosperm ratio. Thus, embryo and endosperm interact in determining embryo/endosperm size balance. Among genes associated with embryo/endosperm size, REDUCED EMBRYO genes, whose loss‐of‐function causes a phenotype opposite to ge, are revealed to regulate endosperm size upstream of GE. To fully understand the embryo–endosperm size control, the genetic network of the related genes should be elucidated.     

The ANGULATA7 gene encodes a DnaJ‐like zinc finger‐domain protein involved in chloroplast function and leaf development in Arabidopsis

The characterization of mutants with altered leaf shape and pigmentation has previously allowed the identification of nuclear genes that encode plastid‐localized proteins that perform essential functions in leaf growth and development. A large‐scale screen previously allowed us to isolate ethyl methanesulfonate‐induced mutants with small rosettes and pale green leaves with prominent marginal teeth, which were assigned to a phenotypic class that we dubbed Angulata. The molecular characterization of the 12 genes assigned to this phenotypic class should help us to advance our understanding of the still poorly understood relationship between chloroplast biogenesis and leaf morphogenesis. In this article, we report the phenotypic and molecular characterization of the angulata7‐1 (anu7‐1) mutant of Arabidopsis thaliana, which we found to be a hypomorphic allele of the EMB2737 gene, which was previously known only for its embryonic‐lethal mutations. ANU7 encodes a plant‐specific protein that contains a domain similar to the central cysteine‐rich domain of DnaJ proteins. The observed genetic interaction of anu7‐1 with a loss‐of‐function allele of GENOMES UNCOUPLED1 suggests that the anu7‐1 mutation triggers a retrograde signal that leads to changes in the expression of many genes that normally function in the chloroplasts. Many such genes are expressed at higher levels in anu7‐1 rosettes, with a significant overrepresentation of those required for the expression of plastid genome genes. Like in other mutants with altered expression of plastid‐encoded genes, we found that anu7‐1 exhibits defects in the arrangement of thylakoidal membranes, which appear locally unappressed.