Late embryo-defective mutants of Arabidopsis

The embryo-defective (emb) mutants of Arabidopsis constitute a large and diverse group of mutants disrupted in a broad range of embryonic processes, including morphogonesis, cell differentiation, and maturation programs. This report describes a subset of these mutants, the late embryo defectives, which develop beyond the globular stage of embryogenesis but fail to complete normal morphogenesis. A representative sample of 12 late mutants was chosen for this study, patterns of morphogenesis were characterized, the germination potential of mutant seeds was investigated, and additional mutant alleles within the collection were identified. Morphological defects in mutant embryos became apparent during the heart stage of development, when embryos normally begin the rapid cell division and expansion required for the completion of morphogenesis. Despite their morphological abnormalities, mutant embryos often germinated from dry seed, demonstrating that genetic programs required for the establishment of desiccation tolerance remained intact. Mutant seedlings displayed a wide range of developmental abnormalities, including altered morphology, lack of pigmentation, dwarfism, and disorganized vegetative growth. One late mutant was found to be allelic to an early embryo defective that arrests at the globular stage. These results suggest that a number of late EMB genes encode basic cellular and metabolic functions needed for cell division, enlargement, and embryonic growth. The rapid growth and metabolic changes that occur at the heart stage may present a barrier to normal development in the late mutants, resulting in altered embryo morphology and other developmental defects. It is proposed that many Arabidopsis mutants with abnormal embryo and seedling morphology are not defective in the regulation of pattern formation or morphogenesis, but rather in fundamental physiological and cellular processes required for the completion of normal growth and development. © 1995 Wiley-Liss, Inc.     

Hierarchical regulation of organ differentiation during embryogenesis in rice

In plants, genetic mechanisms leading to shoot and root formation are almost unknown. Because basic body organization of such organisms is established during embryogenesis, induction and isolation of embryonic mutants is a promising approach to the study of plant development. The study of available embryonic mutants of rice indicates the existence of three major developmental processes taking place during embryogenesis before morphogenetic events start: determination of organ differentiation, positional regulation of organs and size regulation of the embryo. The consideration of specific rice mutants supports the existence of two types of mutations in each regulatory process, one affecting the embryo as a whole and the second concerning more restricted embryonal regions. A hierarchical type of control of rice embryogenesis is suggested.     

The rice mutant dwarf bamboo shoot 1: a leaky mutant of the NACK-type kinesin-like gene can initiate organ primordia but not organ development

That plant dwarfism is caused by hormonal defects related to gibberellin and brassinosteroid has been well documented. Other contributing elements, however, have not been elucidated. Here, we report on one of the most severe dwarf mutants of rice, dwarf bamboo shoot 1 (dbs1). Most mutant plants died within 1 month after sowing, but a few (5.2%) survived and grew. Vacuolation enlarged cells in the leaf primordia and seminal root before abortion, which disrupted the organized cell files in these organs. Relative to the severe defects in shoot and root growth, the overall structure of the dbs1 embryo was almost normal. Similarly, initiation and organogenesis of the leaf primordia at the shoot apical meristem and those of the lateral root primordia at the root elongation zone occurred normally. These observations suggest that DBS1 is involved in the growth and development of organs but not in organ initiation or organogenesis. Positional cloning of DBS1 revealed that it encoded a NACK-type kinesin-like protein (OsNACK), homologous to the essential components of a mitogen-activated protein kinase cascade during plant cytokinesis. A BLAST search indicated that DBS1 was the only gene encoding the OsNACK-type protein in the rice genome, and the dbs1 mutant produced only small amounts of the translatable DBS1 mRNA. Thus, we conclude that the dbs1 mutation causes a severe defect in DBS1 function but does not completely shut it down. We discuss the leaky phenotype of dbs1 under the restricted functioning of OsNACK.     

Rice DECUSSATE controls phyllotaxy by affecting the cytokinin signaling pathway

Phyllotaxy is defined as the spatial arrangement of leaves on the stem. The mechanism responsible for this extremely regular pattern is one of the most fascinating enigmas in plant biology. In this study, we identified a gene regulating the phyllotactic pattern in rice. Loss‐of‐function mutants of the DECUSSATE (DEC) gene displayed a phyllotactic conversion from normal distichous pattern to decussate. The dec mutants had an enlarged shoot apical meristem with enhanced cell division activity. In contrast to the shoot apical meristem, the size of the root apical meristem in the dec mutants was reduced, and cell division activity was suppressed. These phenotypes indicate that DEC has opposite functions in the shoot apical meristem and root apical meristem. Map‐based cloning revealed that DEC encodes a plant‐specific protein containing a glutamine‐rich region and a conserved motif. Although its molecular function is unclear, the conserved domain is shared with fungi and animals. Expression analysis showed that several type A response regulator genes that act in the cytokinin signaling pathway were down‐regulated in the dec mutant. In addition, dec seedlings showed a reduced responsiveness to exogenous cytokinin. Our results suggest that DEC controls the phyllotactic pattern by affecting cytokinin signaling in rice.     

The Petunia tra1 gene controls cell elongation and plant development, and mediates responses to cytokinins

The molecular control of cell elongation, one of the basic processes of plant morphogenesis, is still largely not understood. This paper describes a Petunia hybrida mutant of dumpy phenotype, trapu, which identifies tra1, a gene required for cell elongation and mediating responses to applied cytokinin. This mutant displayed an extreme reduction in length, due to a single recessive mutation which was expressed in every part of the plant and during the entire life of the plant, including the mature embryo. The mutant was unable to flower. The mutant roots, as well as the leafy organs, were short and thick, and the root elongation zone, hypocotyl and petioles were absent. The mutant plantlets responded neither to applied auxin nor to gibberellin, indicating that this phenotype was not caused by a deprivation of these phytohormones. However, unlike the wildtype, the mutant growth was stimulated by applied cytokinin, even though its morphology remained abnormal. A histological study revealed the presence of all tissue types in normal positions, including root hairs and vascular bundles. The mutant's cells were rounder in every tissue. Both shoot and root meristems were disorganized, without consistent cell shape and size. The regular cell files, which are typical of a normal root apex organization, were totally absent in the mutant root apex. Indirect immunofluorescence of α-tubulin on root apices showed the cortical microtubules in the mutant cells to be unable to form the parallel arrays in elongating cells and the preprophase band in dividing cells. This default resulted in the prevention of unidirectional cell elongation and formation of regular cell files, thus causing the trapu phenotype. This paper discusses the similarities and differences of trapu to the Arabidopsis mutants, fass and ton, trapu confirming that the establishment of plant body pattern and differentiation can be dissociated from cell elongation.     

Defective kernel mutants of maize. I. Genetic and lethality studies

A planting of 3,919 M₁ kernels from normal ears crossed by EMS-treated pollen produced 3,461 M₁ plants and 3,172 selfed ears. These plants yielded 2,477 (72%) total heritable changes; the selfed ears yielded 2,457 (78%) recessive mutants, including 855 (27%) recessive kernel mutants and 8 (0.23%) viable dominant mutants. The ratio of recessive to dominant mutants was 201:1. The average mutation frequency for four known loci was three per 3,172 genomes analyzed. The estimated total number of loci mutated was 535 and the estimated number of kernel mutant loci mutated was 285. Among the 855 kernel mutants, 432 had a nonviable embryo, and 59 germinated but had a lethal seedling. A sample of 194 of the latter two types was tested for heritability, lethality, chromosome arm location and endosperm-embryo interaction between mutant and nonmutant tissues in special hyper-hypoploid combinations produced by manipulation of B-A translocations. The selected 194 mutants were characterized and catalogued according to endosperm phenotype and investigated to determine their effects on the morphology and development of the associated embryo. The possibility of rescuing some of the lethal mutants by covering the mutant embryo with a normal endosperm was investigated. Ninety of these 194 mutants were located on 17 of the 18 chromosome arms tested. Nineteen of the located mutants were examined to determine the effect of having a normal embryo in the same kernel with a mutant endosperm, and vice versa, as compared to the expression observed in kernels with both embryo and endosperm in a mutant condition. In the first situation, for three of the 19 mutants, the mutant endosperm was less extreme (the embryo helped); for seven cases, the mutant endosperm was more extreme (the embryo hindered); and for nine cases, there was no change. In the reverse situation, for four cases the normal endosperm helped the mutant embryo; for 14 cases there was no change and one case was inconclusive.     

Phenotypic diversity of 188 rice embryo mutants

We have identified 188 embryo mutants of rice and characterized them into six groups based on their phenotypes: (1) embryoless in mature seed, (2) deletion of embryonic organ(s), (3) abnormal position of embryonic organs, (4) abnormal embryo size, (5) defect in organ morphology, and (6) variable abnormal phenotypes in spite of single mutations. Three types of organless mutants are obtained: small globular embryo, club-shaped embryo, and large embryo. Although 12 shootless mutants derived from at least three loci are identified, only three radicleless mutants are recovered, which produce normal adventitious roots after germination. In reduced embryo mutants, every embryonic organ is reduced, in contrast to giant embryo mutants in which only scutellum is enlarged. Considerable number of mutants are categorized into (5) and (6) in the above. These diverse embryo mutants would serve as promising materials for genetic study of embryogenesis. © 1995 Wiley-Liss, Inc.     

Mutations associated with floral organ number in rice

How floral organ number is specified is an interesting subject and has been intensively studied in Arabidopsis thaliana. In rice (Oryza sativa L.), mutations associated with floral organ number have been identified. In three mutants of rice, floral organ number 1 (fon1) and the two alleles, floral organ number 2-1 (fon2-1) and floral organ number 2-2 (fon2-2), the floral organs were increased in number centripetally. Lodicules, homologous to petals, were rarely affected, and stamens were frequently increased from six to seven or eight. Of all the floral organs the number of pistils was the most frequently increased. Among the mutants, fon1 showed a different spectrum of organ number from fon2 -1 and fon2 -2. Lodicules were the most frequently affected in fon1, but pistils of more than half of fon1 flowers were unaffected; in contrast, the pistils of most flowers were increased in fon2 -1 and fon2-2. Homeotic conversion of organ identity was also detected at a low frequency in ectopically formed lodicules and stamens. Lodicules and stamens were partially converted into anthers and stigmas, respectively. Concomitant with the increased number of floral organs, each mutant had an enlarged apical meristem. Although meristem size was comparable among the three mutants and wild type in the early phase of flower development, a significant difference became apparent after the lemma primordium had differentiated. In these mutants, the size of the shoot apical meristem in the embryo and in the vegetative phase was not affected, and no phenotypic abnormalities were detected. These results do not coincide with those for Arabidopsis in which clavatal affects the sizes of both shoot and floral meristems, leading to abnormal phyllotaxis, inflorescence fasciation and increased floral organs. Accordingly, it is considered that FON1 and FON2 function exclusively in the regulation of the floral meristem, not of the vegetative meristem.Abbreviation DIC differential interference contrast This work was supported in part by Grant-in-Aid for Scientific Research on Priority Areas from the Ministry of Education, Science and Culture of Japan.     

Morphology and ultrastructure of 11 barley shrunken endosperm mutants

Summary Eleven Na-azide induced barley shrunken endosperm mutants expressing xenia (sex) were characterized genetically and histologically. All mutants have reduced kernel size with kernel weights ranging from 11 to 57% of the wild type. With one exception, the mutant phenotypes are ascribable to single recessive mutant alleles, giving rise to a ratio of 31 of normal and shrunken kernels on heterozygous plants. One mutant (B10), also monofactorially inherited, shows a gene dosage dependent pattern of expression in the endosperm. Among the 8 mutants tested for allelism, no allelic mutant genes were discovered. By means of translocation mapping, the mutant gene of B10 was localized to the short arm of chromosome 7, and that of B9 to the short arm of chromosome 1. Based on microscopy studies, the mutant kernel phenotypes fall into three classes, viz. mutants with both endosperm and embryo affected and with a non-viable embryo, mutants with both endosperm and embryo affected and with a viable embryo giving rise to plants with a clearly mutant phenotype, and finally mutants with only the endosperm affected and with a normal embryo giving rise to plants with normal phenotype. The mutant collection covers mutations in genes participating in all of the developmental phases of the endosperm, i.e. the passage from syncytial to the cellular endosperm, total lack of aleurone cell formation and disturbance in the pattern of aleurone cell formation. In the starchy endosperm, varying degrees of cell differentiation occur, ranging from slight deviations from wild type to complete loss of starchy endosperm traits. In the embryo, blocks in the major developmental phases are represented in the mutant collection, including arrest at the proembryo stage, continued cell divisions but no differentiation, and embryos deviating only slightly from the wild type.     

Ac/Ds transposon mutagenesis in Arabidopsis thaliana: mutant spectrum and frequency of Ds insertion mutants

Using a two-component Ac/Ds system consisting of a stabilized Ac element (Ac_c1) and a non-autonomous element (Ds_A), 650 families of plants carrying independent germinal Ds_A excisions/transpositions were isolated. Progenies of 559 of these Ac_c1/Ds_A families, together with 43 families of plants selected for excision/transposition of wild-type (wt)Ac, were subjected to a broad screening program for mutants exhibiting visible alterations. This resulted in the identification of 48 mutants showing a wide variety of mutant phenotypes, including embryo lethality (24 mutants), chlorophyll defects (5 mutants), defective seedlings (2 mutants), reduced fertility (5 mutants), reduced size (3 mutants), altered leaf morphology (2 mutants), dark green, unexpanded rosette leaves (3 mutants), and aberrant flower or shoot morphology (4 mutants). To test whether these mutants were due to transposon insertions, a series of Southern blot experiments was performed on 28 families, comparing in each case several mutant plants with others showing the wild-type phenotype. A preliminary analysis revealed in 4 of the 28 families analyzed a common, novel Ds_A fragment in all mutant plants, which was present only in heterozygous plants with wt phenotype, as expected for Ds_A insertion mutations. These four mutants included two showing embryo lethality, one with dark green, unexpanded rosette leaves and stunted inflorescences, and one with curly growth of stems, leaves and siliques. Further evidence for Ds_A insertion mutations was obtained for one embryo lethal mutant and for the stunted mutant, while in case of the second embryo lethal mutant, the Ds_A insertion could be separated from the mutant locus by genetic recombination.     

An expanded role for the TWN1 gene in embryogenesis: defects in cotyledon pattern and morphology in the twn1 mutant of Arabidopsis (Brassicaceae)

The suspensor is a specialized basal structure that differentiates early in plant embryogenesis to support development of the embryo proper. Suspensor differentiation in Arabidopsis is maintained in part by the TWIN1 (TWN1) gene, which suppresses embryogenic development in suspensor cells: twn1 mutants produce supernumerary embryos via suspensor transformation. To better understand mechanisms of suspensor development and further investigate the function of TWN1, we have characterized late-embryo and post-embryonic development in the twn1 mutant, using seedling culture, microscopy, and genetics. We report here that the twn1 mutation disrupts cotyledon number, arrangement, and morphology and occasionally causes partial conversion of cotyledons into leaves. These defects are not a consequence of suspensor transformation. Thus, in addition to its basal role in suspensor differentiation, TWN1 influences apical pattern and morphology in the embryo proper. To determine whether other genes can similarly affect both suspensor and cotyledon development, we looked for twinning in Arabidopsis mutants previously identified by their abnormal cotyledon phenotypes. One such mutant, amp1, produced a low frequency of twin embryos by suspensor transformation. Our results suggest that mechanisms that maintain suspensor identity also function later in development to influence organ formation at the embryonic shoot apex. We propose that TWN1 functions in cell communication pathways that convey local positional information in both the apical and basal regions of the Arabidopsis embryo.     

Developmental consequences of the <Emphasis Type="Italic">tumorous shoot development1</Emphasis> mutation,a novel allele of the cellulose-synthesizing <Emphasis Type="Italic">KORRIGAN1</Emphasis> gene

This work describes the further characterization of the tumorous shoot development1 (tsd1) mutant of Arabidopsis thaliana, which develops disorganized tumorous-like shoot tissue instead of organized leaves and stems. Map-based cloning revealed that tsd1 is a novel strong allele of the KOR1 gene, encoding a membrane-bound endo-1,4-β-d-glucanase involved in cellulose synthesis. To study developmental changes accompanying the aberrant growth of the tsd1 mutant, patterning in the meristems and the hormonal status were analysed by marker genes. Expression of key regulators of meristem maintenance, the CLV3 and STM genes, indicated the presence of numerous meristems in the tsd1 shoot callus. Expression of the LFY::GUS marker supported the ability of the tsd1 callus to form organ primordia, which however failed to develop further. An epidermal marker showed that the L1 layer was maintained only in distinct areas of the tsd1 callus, which could be a reason of disorganized shoot growth. In the tsd1 root meristem, quiescent center activity was lost early after germination, which caused differentiation of the root meristem. The spatial expression of genes reporting the auxin and cytokinin status was altered in the tsd1 mutant. Modifying the endogenous levels of these hormones partially rescued shoot and root development of the tsd1 mutant. Together, the work shows that TSD1/KOR1 is required for maintaining a correct meristematic pattern and organ growth as well as for a normal hormonal response.     

single cotyledon (sic) mutants of pea and their significance in understanding plant embryo development

Angiosperms are divided into two distinct classes—the dicotyledons (dicots) and monocotyledons (monocots)—based in part on the number of cotyledons in mature embryos. In this paper, we describe single‐cotyledon pea mutants, termed sic (single cotyledon), all of which show a degree of fusion between the cotyledons. The fusion in sic1 is along the margin of one cotyledon and is less complete than in sic2 embryos, but the effects of the mutations are additive in the double mutant. Occasionally sic2 mutants will show fusion of the two cotyledons into one cylindrical embryo in which the shoot apex becomes surrounded by the cotyledons. Both sic1 and sic2 mutants produce fertile plants. In the sic3 embryo, a single cotyledon is generated under the shoot apex that breaks the vascular connection between root and shoot, causing embryo lethality. The pattern of cotyledon development in all these mutants is identified by in situ mRNA hybridization and antibody labeling, using the storage protein vicilin as a cotyledon‐specific marker. These patterns indicate that the joining of the cotyledons was due to zonal growth. The results indicate that there are genes in pea that influence the positioning and the morphology of the cotyledon. A model for cotyledon development in pea is proposed that is based on the regulation of the positioning of cell clusters by the sic genes. Dev. Genet. 25:11–22, 1999. © 1999 Wiley‐Liss, Inc.     

Ascorbic acid improves conversion of white spruce somatic embryos

Summary The effects of exogenous applications of ascorbic acid on white spruce somatic embryogenesis were examined. Increasing concentrations of ascorbate (1 μM to 100 μM) in the germination medium enhanced somatic embryo conversion in a linear fashion. At the optimal ascorbate level (100 μM) the number of embryos able to undergo normal conversion, i.e., emergence of both root and shoot, increased from 34% (control) to 58%. The effect of ascorbate had a more pronounced effect on shoot growth than on root emergence; and at 100 μM ascorbate, the percentage of embryos able to produce new leaf primordia increased from 47% (control) to 79%. Root emergence increased slightly from 64% in the control embryos to 74% in the presence of ascorbic acid. The ascorbate-treated embryos were characterized by an enlarged apical region, presumably due to a larger number of leaf primordia produced, and by dark green leaves. When allowed to grow further, these embryos were able to develop into normal plantlets.     

Evidence of a role for endogenous electrical fields in chick embryo development.

We have tested directly the hypothesis that the endogenous electrical field in the chick embryo plays a causal role in development. Conductive implants, which shunt currents out of the embryo and thus alter the internal field, were placed under the dorsal skin at the mid-trunk level of stage 11-15 embryos. Currents leaving the posterior intestinal portal (p.i.p.) of these embryos were reduced by an average of 30%. Control embryos receiving non-conductive implants showed no change in p.i.p. currents. In the group receiving current shunts, 92% of the embryos exhibited some developmental abnormality. Only 11% of the control group displayed defects. The most common defect in the experimental group (81%) was in tail development. Tail defects ranged from complete absence to the formation of a normal length, but morphologically abnormal tail. Internally, tail structures (neural tube, notochord and somites) were frequently absent or aberrantly formed. In 33% of the experimental embryos, the notochord continued lengthening in the absence of any other tail development. This led to the formation of ourenteric outgrowths from the hindgut. Defects in limb bud and head development were also found in experimentally treated embryos, but at a much lower frequency than tail defects. The abnormalities observed in experimental embryos were very similar to those produced naturally in rumpless mutant chicks. A vibrating probe analysis of these mutants (from both dominant and recessive strains) showed that currents leaving the p.i.p. were significantly lower in phenotypically abnormal mutants than in wild-type and phenotypically normal mutant embryos from both strains. There was no apparent correlation between the average transepithelial potential (TEP) of these mutants and the development of tail abnormalities. The possible role of endogenous electrical fields in chick tail development is discussed.     

The indeterminate gametophyte1 gene of maize encodes a LOB domain protein required for embryo Sac and leaf development

Angiosperm embryo sac development begins with a phase of free nuclear division followed by cellularization and differentiation of cell types. The indeterminate gametophyte1 (ig1) gene of maize (Zea mays) restricts the proliferative phase of female gametophyte development. ig1 mutant female gametophytes have a prolonged phase of free nuclear divisions leading to a variety of embryo sac abnormalities, including extra egg cells, extra polar nuclei, and extra synergids. Positional cloning of ig1 was performed based on the genome sequence of the orthologous region in rice. ig1 encodes a LATERAL ORGAN BOUNDARIES domain protein with high similarity to ASYMMETRIC LEAVES2 of Arabidopsis thaliana. A second mutant allele of ig1 was identified in a noncomplementation screen using active Mutator transposable element lines. Homozygous ig1 mutants have abnormal leaf morphology as well as abnormal embryo sac development. Affected leaves have disrupted abaxial-adaxial polarity and fail to repress the expression of meristem-specific knotted-like homeobox (knox) genes in leaf primordia, causing a proliferative, stem cell identity to persist in these cells. Despite the superficial similarity of ig1-O leaves and embryo sacs, ectopic knox gene expression cannot be detected in ig1-O embryo sacs.     

The role of OsBRI1 and its homologous genes, OsBRL1 and OsBRL3, in rice

Since first identifying two alleles of a rice (Oryza sativa) brassinosteroid (BR)-insensitive mutant, d61, that were also defective in an orthologous gene in Arabidopsis (Arabidopsis thaliana) BRASSINOSTEROID INSENSITIVE1 (BRI1), we have isolated eight additional alleles, including null mutations, of the rice BRI1 gene OsBRI1. The most severe mutant, d61-4, exhibited severe dwarfism and twisted leaves, although pattern formation and differentiation were normal. This severe shoot phenotype was caused mainly by a defect in cell elongation and the disturbance of cell division after the determination of cell fate. In contrast to its severe shoot phenotype, the d61-4 mutant had a mild root phenotype. Concomitantly, the accumulation of castasterone, the active BR in rice, was up to 30-fold greater in the shoots, while only 1.5-fold greater in the roots. The homologous genes for OsBRI1, OsBRL1 and OsBRL3, were highly expressed in roots but weakly expressed in shoots, and their expression was higher in d61-4 than in the wild type. Based on these observations, we conclude that OsBRI1 is not essential for pattern formation or organ initiation, but is involved in organ development through controlling cell division and elongation. In addition, OsBRL1 and OsBRL3 are at least partly involved in BR perception in the roots.     

Loss-of-function of a rice brassinosteroid biosynthetic enzyme,C-6 oxidase,prevents the organized arrangement and polar elongation of cells in the leaves and stem

Molecular genetic and physiological studies on brassinosteroid (BR)-related mutants of dicot plants have revealed that BRs play important roles in normal plant growth and development. However, little is known about the function of BR in monocots (grasses), except for the phenotypic analysis of a rice mutant partially insensitive to BR signaling. To investigate the function of BR in monocots, we identified and characterized BR-deficient mutants of rice, BR-deficient dwarf1 (brd1). The brd1 mutants showed a range of abnormalities in organ development and growth, the most striking of which were defects in the elongation of the stem and leaves. Light microscopic observations revealed that this abnormality was primarily owing to a failure in the organization and polar elongation of the leaf and stem cells. The accumulation profile of BR compounds in the brd1 mutants suggested that these plants may be deficient in the activity of BR C-6 oxidase. Therefore, we cloned a rice gene, OsDWARF, which has a high sequence similarity to the tomato C-6 oxidase gene, DWARF. Introduction of the wild-type OsDWARF gene into brd1 rescued the abnormal phenotype of the mutants. The OsDWARF gene was expressed at a low level in all of the examined tissues, with preferential expression in the leaf sheath, and the expression was negatively regulated by brassinolide treatment. On the basis of these findings, we discuss the biological function of BRs in rice plants.     

Arabidopsis mutants with increased organ regeneration in tissue culture are more competent to respond to hormonal signals

Shoots and roots can be regenerated through organogenesis in tissue culture by subjecting plant explants to the appropriate regime of hormone treatments. In an effort to understand the control of shoot organogenesis, we screened for mutants in Arabidopsis thaliana (L.) Heynh. Columbia ecotype for enhanced shoot development at sub-optimal concentrations of cytokinin. Mutants in four different complementation groups were identified, one of which represents a new locus named increased organ regeneration1 (ire1) and another that is allelic to the previously identified pom1/erh2 mutant. Although the mutants were selected for their response to cytokinin, they were neither hypersensitive to, nor were they over-producers of cytokinins. The mutations identified in this study not only promote more robust shoot production in tissue culture, but also enhance green-callus and root formation. We interpret this to mean that, in tissue culture, IRE genes act before organ specification during the time when root explants acquire the competency to respond to organ formation signals. In normal plant development, IRE genes may down-regulate the competency of vegetative tissue to respond to hormonal signals involved in shoot and root organogenesis.