ABSTRACT
The monopteros (mp) gene contributes to apical-basal pattern formation in the Arabidopsis embryo. mp mutant seedlings lack basal body structures such as hypocotyl, radicle and root meristem, and this pattern deletion has been traced back to alterations in the octant-stage embryo. Cells of the embryo proper and the uppermost cell of the suspensor fail to establish division patterns that would normally generate the basal body structures. The resulting absence of a morphological axis seems to be responsible for another phenotypic trait of mp seedlings, variable positioning of cotyledons. This relationship is suggested by weak mp seedling phenotypes in which the presence of a short hypocotyl is correlated with normal arrangement of cotyledons. Root formation has been induced in mp seedlings grown in tissue culture. This result supports the notion that the mp gene is required for organising the basal body region, rather than for making the root, in the developing embryo.
INTRODUCTION
In flowering plants, the body organisation is generated by two distinct processes. Embryonic pattern formation lays down the primary organisation of the plant body, as represented by the seedling, including the meristems of the shoot and the root. The meristems then take over to produce the adult plant during postembryonic development (Steeves and Sussex, 1989). The primary body organisation of the seedling has been viewed as a superimposition of two patterns: an apical-basal pattern along the main body axis of polarity and a radial pattern perpendicular to the axis (Jürgens et al., 1991; Mayer et al., 1991). Each pattern consists of an array of morphologically distinct elements. Shoot meristem, cotyledon(s), hypocotyl, radicle (embryonic root) and root meristem are elements of the apical-basal pattern while the three major tissue types, such as epidermis, ground tissue and vascular tissue, are concentrically arranged to give the radial pattern. With the exception of the shoot meristem, the primordia of pattern elements are morphologically recognisable in the heart-shaped embryo.
How the basic body pattern is generated in the plant embryo is unknown. One way to analyse this process is a genetic approach: mutants with relevant phenotypes are isolated and characterised in order to identify genes specifically involved in embryonic pattern formation. This approach has been highly successful in favourable animal species such as Drosophila and Caenorhabditis, providing a basis for subsequent analysis of underlying molecular mechanisms (reviews by Ingham, 1988, and Schnabel, 1991). Developmental mutants resulting in various types of embryo defects have also been described in several plant species (reviews by Meinke, 1991, and Sheridan, 1988; Clark and Sheridan, 1991). The prevalent class of mutations arrest embryogenesis, and it is thus not clear from the mutant phenotypes whether embryonic pattern formation or other developmental processes are affected. A complementary approach was taken in Arabidopsis thaliana by focusing on the seedling phenotypes of embryonic mutants that did complete embryogenesis (Jürgens et al., 1991). A set of putative pattern genes were thus identified by mutations that affect different aspects of the seedling organisation (Mayer et al., 1991).
Four genes, including the monopteros (mp) gene, appear to be involved in apical-basal pattern formation. Mutations in the mp gene eliminate the basal pattern elements, hypocotyl, radicle and root meristem. Here, we present a detailed analysis of mp mutant embryos and seedlings, including tissue-culture experiments in which mutant seedlings were assayed for the ability to form roots. Our results suggest that the mp gene is primarily required in the early embryo for organising the development of the basal body region.
MATERIALS AND METHODS
Plant growth conditions, plant strains and genetic crosses
Plants were grown as previously described (Mayer et al., 1993). The wild-type strain used was the Landsberg erecta (Ler) ecotype. For mapping the mp gene, we used the marker strain W100 (an ap1; er py; hy-2 gl-1; bp cer-2; ms-1 tt-3) kindly provided by M. Koornneef, Agricultural University, Wageningen, The Netherlands (for description of mutants, see Koornneef et al., 1983; Koornneef, 1990). The monopteros (mp) mutants were isolated on the basis of their seedling phenotypes following EMS mutagenesis of Ler seeds (Mayer et al., 1991). Genetic crosses were done as previously described (Mayer et al., 1993). In complementation tests, seedling progeny (at least 60) from 3 or more cross-pollinated flowers were phenotyped on agar plates.
Recombination mapping
The mp gene was mapped against 9 marker mutations in the W100 strain. mpU21 heterozygous plants were crossed with homozygous W100 marker plants and F1 plants heterozygous for mp were identified by the phenotypes of their progeny. Individual F2 plants were phenotyped for the recessive markers and analysed for the production of mp mutant seedlings. The recombination frequency (RF) between mp and each marker was determined as RF=x/(2-x), with x representing the proportion of mp heterozygous plants among all F2 plants homozygous for this marker. Map distances were calculated from the recombination frequencies using the mapping function. For 8 markers, the x values were close to 66% (58 – 71%), indicating free segregation whereas only 33% (11/33) of the F2 plants homozygous for an were also heterozygous for mp. From this x value, a recombination frequency (RF) of 20% and a map distance of 25.5 cM between an and mp were calculated.
Phenotypic analysis
For the analysis of seedling phenotypes, seeds were plated on medium containing 0.3% agar and 50 μg/ml ampicillin, stored for several days at 4°C in the dark to break dormancy and then germinated in the light (constant illumination, 24°C). Seedling phenotypes were usually analysed about 7 days after germination, using an Olympus stereoscope and an Olympus Ti-4 camera attached to it.
Whole-mount preparations were used for microscopic analysis of embryo and seedling phenotypes. Embryos or 7-day old seedlings were fixed for 1 – 4 hours in ethanol/acetic acid (6:1) at room temperature. After several washes in 100% ethanol and finally in 70% ethanol, embryos or seedlings were mounted in a mixture of chloralhydrate/glycerol/water (8:1:2) and cleared for about 1 hour at room temperature. Whole-mount preparations could be stored at room temperature for at least several weeks. Whole-mount preparations were used to detect specific deviations of mp mutants from wild-type embryo development, by analysing the progeny of mp heterozygous and wild-type plants from the same lines. Large numbers of wild-type and mutant embryos were thus compared in order to assess the specificity of defects before embryos were analysed in histological sections.
For histological analysis of embryos, ovules were collected from siliques of appropriate ages, washed in PBT (50 mM sodium phosphate pH 7.2, 0.15 % Tween 20) and fixed in a mixture of 4% paraformaldehyde, 0.25% glutaraldehyde in 50 mM sodium phosphate (pH 7.2) at 4°C for 1 or 2 days. Fixed ovules were processed for embedding in Spurr’s resin (Spurr, 1969). Ovules were dehydrated in a series of increasing concentrations of acetone. After several washes in 100% acetone, Spurr’s embedding medium was added in increasing concentrations over a period of 4 hours and finally exchanged several times against fresh embedding medium to remove all traces of acetone. After hardening (overnight at 60°C), sections, 4.5 μm thick, were cut with a Reichert-Jung microtome, placed onto polylysine-coated microscope slides, stained with toluidine-blue and mounted in Spurr’s medium. Photographs of sections were taken with a Zeiss Axiophot microscopecamera, using an Agfa-Pan film (25 ASA).
Tissue culture
Seeds from mutant lines were surface-sterilised in 5% calcium hypochloride/0.15% Tween 20 for 8 minutes, washed at least 4 times in water and plated on medium containing 0.3% agar and 50 μg/ml ampicillin. After germination, the seedlings were kept on these plates for 7 days (constant illumination, 24°C) to allow for the completion of cell expansion. Mutant seedlings were manipulated with foreceps in either of two ways, depending on the allele under investigation.
Mutant seedlings with weak alleles were wounded immediately below the cotyledons; bisection was attempted but not always achieved. The apical part, including the shoot meristem and the cotyledons, was placed on fresh medium containing 0.3% agar, 50 μg/ml ampicillin and half-strength Murashige-Skoog basal medium (Murashige and Skoog, 1962), supplemented with 0.5% sucrose and 3 μg/ml indole butyric acid (IBA). The plates were sealed with parafilm and kept under constant illumination at 24°C for several weeks.
Mutant seedlings with strong mp alleles were dissected and pieces of tissue (mostly cotyledon, occasionally including meristematic tissue) were cultured on a medium of similar composition as above, but supplemented with 0.2 μg/ml kinetin, in addition to 0.3 μg/ml IBA. After three weeks, explants were transferred to fresh medium containing 0.3 μg/ml IBA as the only hormone and scored for root development at weekly intervals.
RESULTS
Genetic analysis of monopteros mutants
A large-scale screen for putative pattern mutants in Ara bidopsis yielded a group of mutants with very similar seedling phenotypes: the basal pattern elements, root and hypocotyl, were deleted, and the number and relative position of the cotyledons were variably altered (Fig. 1A). This group of mutants was named monopteros (mp) after the frequent occurrence of only a single cotyledon in mutant seedlings, and complementation analysis established one gene with 11 mutant alleles (Mayer et al., 1991). Two additional mutants with similar phenotypes, which had initially shown aberrant segregation ratios, also proved to be mp alleles. All mutant alleles were tested in reciprocal crosses with each of three reference alleles (mpTÜ399, mpT1 and mpU21), and no complementation was observed. Upon outcrossing to wild-type, normal segregation ratios close to 25% were observed for all 13 alleles. Thus, the monopteros phenotype appears to result from recessive mutations in a single nuclear gene that is normally active in the embryo but has no apparent function in the gametophytes. The mp gene was mapped to the first chromosome, approximately 25 cM from the angustifolia (an) gene (see Materials and methods). This initial mapping result was confirmed by localising the mp gene on RFLP maps as a first step towards molecular cloning (Chang et al., 1988; Nam et al., 1989; C. Hardtke and T.B., unpublished data).
Two groups of mp alleles were distinguished by morphological criteria: most notably, one group of 3 alleles (mpG92, mpU348 and mpT366) occasionally produced mutant seedlings with a short hypocotyl whereas this was never observed for the other 10 alleles, which were therefore classified as strong (for details, see later). Trans-heterozygotes of weak and strong alleles showed typical features of the weak phenotype, suggesting that the weak alleles have residual mp gene activity. We will first describe the seedling phenotype of strong alleles which very likely results from complete inactivation of the mp gene.
The seedling phenotype of strong mp alleles
All strong mp alleles produce essentially the same seedling phenotype: basal structures are deleted while the arrangement of cotyledons may be normal or variably altered (Fig. 1A). The mp gene thus seems to be absolutely required for the formation of basal structures but not for the spatial arrangement of cotyledons (see later). Disregarding the apical variability in this section, we compare organ differentiation in mutant and wild-type seedlings.
The mp seedling phenotype has been described as a specific type of apical-basal pattern deletion in that apical structures such as shoot meristem and cotyledons are present whereas basal structures such as hypocotyl, radicle and root meristem are missing (Mayer et al., 1991). mp seedlings end basally in a conical structure we have named ‘basal peg’ which is attached to the cotyledons (Fig. 1B). We have analysed the ‘basal peg’ in order to determine whether this structure is unique to mp seedlings or whether it corresponds to one or another basal element of the wild-type seedling. The ‘basal peg’ does not show any root-specific morphological features, such as root hairs, root cap etc., nor does it show the internal differentiation that characterises the hypocotyl (Fig. 2A-D). The wild-type hypocotyl has a concentric arrangement of different cell types, and this radial pattern is invariant along the cylindrical hypocotyl (Fig. 2A,C). By contrast, the ‘basal peg’ contains large cells without any morphological distinctions (Fig. 2B,D). In addition, the ‘basal peg’ is variably oriented relative to the cotyledons, in contrast to the fixed position of the hypocotyl (see later; Figs 3, 4). Thus, the ‘basal peg’ may be regarded as a unique structure of mp seedlings that develops by default (see section on embryogenesis and Discussion).
In contrast to the deletion of basal pattern elements, the apical structures such as cotyledons and shoot meristem are present in mp seedlings and well differentiated. The cotyledons of mp seedlings consist of the tissue types that are found in wild-type cotyledons: epidermis, ground tissue (mesophyll) and vascular tissue. The epidermal layer is composed of tightly connected flat cells, which are typically irregular in shape, and interspersed guard cells of stomata. This organisation, including the average spacing of stomata, is indistinguishable between wild-type and mp cotyledons in both the upper and lower epidermal layers (Fig. 2H,M). No significant differences were observed in the mesophyll layers of mp cotyledons as compared to wild-type (Fig. 2I,L). The cells of the palisade mesophyll are similar in shape and arrangement, and only a single layer of palisade cells was found in cross-sections of both, wild-type and mutant cotyledons (data not shown). Although mp cotyledons may contain supernumerary layers of spongy mesophyll, this feature seems to be rather unspecific as similar defects were also observed in wild-type cotyledons of unusual curvature. By contrast, two specific deviations from the wild-type arrangement were noted for the vascular tissue in the cotyledons of mp seedlings. First, tracheid cells appear incompletely interconnected although they form long strands (Fig. 2K). Preliminary data suggest that these strands nonetheless function sufficiently to support considerable postembryonic growth (T. B., unpublished data). Second, the vascular system is reduced to a centrally located strand in mp cotyledons whereas in wild-type, the central strand is interconnected with two half-circles extending into the blade (Fig. 2E,F). The expression of this vascular phenotype depends on the mp allele studied (see later).
The other apical pattern element, the shoot meristem, is normal in mp mutant seedlings. Little, rapidly growing bulges of small cells, which were observed at germination (Fig. 2G), subsequently formed functional primary leaves (data not shown). The number and time of appearance of the primary leaves was often normal. However, if the cotyledons were abnormally arranged the development of the primary leaves was also affected. Similar effects have been observed for other Arabidopsis seedlings with only a single cotyledon (T. B., unpublished observation).
In summary, the strong seedling phenotype indicates that the mp gene activity is absolutely required for the formation of basal pattern elements such as hypocotyl, radicle and root meristem. By contrast, the two apical pattern elements, shoot meristem and cotyledons, can develop without mp gene activity except that the vascular system of the cotyledons appears to be reduced (see Discussion).
Vascular-system phenotypes reveal differences in allele strength
The strong seedling phenotype as described above is characteristic for ten of the thirteen mp alleles while the remaining three alleles (mpG92, mpU348 and mpT366) produce additional, weaker seedling phenotypes. As the most distinguishing feature, a reduced hypocotyl can occur in seedlings with weak mp alleles (Fig. 3G-I). The hypocotyl is generally much shorter than in wild-type seedlings, although hypocotyls of intermediate length were also found. When analysed in cross-sections, such longer hypocotyls displayed the concentric layers of radial pattern elements as found in wild-type seedlings (data not shown). In order to quantitate differences between seedling phenotypes produced by strong and weak mp alleles, we determined the frequency at which a vascular strand extended basally from the cotyledon(s) for 10 mutant alleles. No such vascular strand was found in mutant seedlings with the 8 strong alleles, in contrast to about 5% of the mutant seedlings with the 2 weak alleles (Fig. 3G-I; Table 1).
Weak and strong mp alleles can also be distinguished by the extent to which the vascular system reticulates in the cotyledons of mutant seedlings. In seedlings with strong alleles, just one vascular strand runs along the midline of the cotyledon(s) in the vast majority of mutant seedlings (Figs 2F, 3A-C; Table 1). By contrast, the vascularisation of cotyledons was more elaborate in 40–50% of mutant seedlings with the weak alleles: the vascular strands were often branched, and even half-circles of vascular strands like those in wild-type seedlings were observed (Fig. 3D-I; Table 1). Separate phenotypic classes such as ‘branched’ and ‘circles’ were established to indicate different degrees of branching although in reality the vascular phenotypes merge. There was no marked correlation between the presence of a hypocotyl and the extent of vascularisation in the cotyledons. For example, the mutant seedling shown in Fig. 3I has an almost complete hypocotyl and yet the vascular system reticulates poorly in the cotyledons.
The vascular-system phenotypes seem to reflect differences between mp alleles rather than effects of unknown second-site modifiers. This conclusion is based on two lines of evidence. First, different sub-lines carrying the same allele produced essentially the same frequency distribution of vascular phenotypes. Second, sub-lines of mp alleles that were established after repeated out-crossing to wild-type, also showed vascular phenotypes not markedly different from those of the original lines. It is thus likely that the weaker seedling phenotypes are due to residual mp gene activity.
The stability of the apical pattern is allele-specific
In wild-type seedlings, the two cotyledons are stably positioned, forming a straight line. Exceptions to this rule are extremely rare and may occur only once in several hundred seedlings. By contrast, mp seedlings often have abnormally positioned cotyledons, with the angle between the cotyledons ranging from less than 180o to almost zero (Fig. 4). Thus, although all apical structures can be formed in the absence of mp gene activity, the stability of their spatial arrangement is reduced in mutant seedlings. In the extreme case, a mp seedling essentially consists of nothing but a single cotyledon (Fig. 4E,F).
In order to quantitate the degree of apical stability in different mp alleles, we classified mutant seedlings with respect to the number and position of the cotyledons. Regardless of other seedling features, three major classes were distinguished: ‘two cotyledons’, which refers to the wild-type arrangement (Fig. 4A,B), ‘single cotyledon’ (Fig. 4E,F), and ‘intermediate’ phenotypes between the two extremes, which includes partially fused cotyledons (Fig. 4C,D). In the 8 strong mp alleles analysed, one-quarter to one-half of the mutant seedlings showed the wild-type arrangement while 30–50% of the mutant seedlings fell into the single-cotyledon class (Table 2). By contrast, two weak alleles predominantly resulted in mutant seedlings with cotyledons positioned in a straight line while less than onefifth of the mutant seedlings represented the singlecotyledon class (Table 2). In order to assess the statistical significance of the result, we determined the phenotypic variability between different sub-lines carrying the same mp allele and compared the mean values for different alleles. As shown in Fig. 5, the single-cotyledon class of seedling phenotypes was reduced for the same two mp alleles that had been classified as weak by the criterion of producing mutant seedlings with a short hypocotyl (see Table 1). In order to determine whether the two phenotypic traits are correlated, mutant seedlings were pre-selected for the occurrence of a short hypocotyl, and 95% (35 of 37) of these seedlings also showed the wild-type arrangement of cotyledons. This result suggests that the hypocotyl may stabilise the spatial arrangement of cotyledons (see Discussion).
Development of monopteros mutant embryos
The mp seedling phenotype had previously been correlated with pattern changes in the heart-shaped embryo (Mayer et al., 1991). We have now studied the development of mutant embryos from early stages in order to determine how the mutant seedling phenotype evolves from primary alterations in the embryo. In the following, we will compare mp and wild-type embryos at four stages of embryogenesis: octant, triangular/early-heart, late-heart and mid-torpedo stages. For the sake of clarity, we will describe the development of symmetric mutant embryos first and the variable features later.
At the octant stage, the wild-type embryo shows a highly reproducible cell arrangement: two tiers of 4 cells each make up the embryo proper, which is derived from the apical daughter cell of the zygote. 6-9 cells, which are the descendants of the basal daughter cell of the zygote, form a filamentous suspensor (Fig. 6A). This cell arrangement is altered in mp mutant embryos: four, rather than two, embryonic cell tiers are attached to a suspensor that consists of the same number of cells as in wild-type (Fig. 6E). The cells of the supernumerary tiers show the intense staining normally characteristic of the embryo proper as opposed to the suspensor cells. The origin of those cells has not been determined (see Discussion). The tiers are often not aligned in parallel, with cell walls running obliquely across an abnormally shaped embryo proper.
Due to the lack of cell migration, different parts of the octant-stage embryo have been correlated with the production of specific elements of the seedling body in Arabidop sis and other crucifers (Vandendries, 1909; Mansfield and Briarty, 1991; Jürgens and Mayer, 1993; Brassica napus: Tykarska, 1976, 1979; Capsella bursa pastoris: Schulz and Jensen, 1968). The cells of the upper tier (ut) will give rise to the shoot meristem and the cotyledons, the derivatives of the lower tier (lt) will produce the hypocotyl, the embryonic root (radicle) and the upper part of the root meristem while the uppermost suspensor cell becomes the hypophysis which, by a precise pattern of cell divisions, will generate the remainder of the root meristem. Following tangential divisions that give off an outer layer of epidermal precursor cells, the ut and lt cells begin to differ in shape and patterns of cell division. The ut cells maintain their isodiametric shape and do not show any preferential direction of division. By contrast, the lt cells elongate in the apical-basal axis and divide in a highly ordered pattern so as to produce precisely oriented cell files (Fig. 6B). These files extend from the basal end of the embryo where the hypophysis has produced a lens-shaped upper daughter cell which eventually gives rise to the centre of the root meristem (Jürgens and Mayer, 1993). The oriented cell divisions of the lt derivatives result in continual growth of the primordia of hypocotyl and radicle, and by the mid-heart stage a morphological axis is well differentiated with respect to the three tissue primordia: the outer epidermis, the ground tissue and the centrally located vascular tissue (Fig. 6C). From the triangular stage on, ut derivatives at two specific sites show increased mitotic activity which leads to the formation and subsequent growth of the cotyledonary primordia (Fig. 6B-D).
Two features that characteristically distinguish mp from wild-type embryos can most clearly be recognised at the triangular/early-heart stage (compare Fig. 6F with 6B). First, all inner cells of mp embryos behave as if they were ut derivatives: they are isodiametric in shape and do not produce the cell files that are characteristic of lt derivatives (compare Figs 6F,K,L with 6B). Second, the uppermost suspensor cell does not undergo the highly stereotyped division pattern of the wild-type hypophysis. Instead, a ‘central pile’ of two to four cells is visible at the basal end of the embryo proper and appears to be contiguous to the suspensor (Fig. 6G,K,L).
Past the triangular stage, the shape of the mp mutant embryo gradually approaches the shape of the mutant seedling, due to the outgrowth of the cotyledonary primordia and the relative narrowing-down of the basal part of the embryo (Fig. 6G,H). Internally, the heart-shaped mp embryo lacks the cell files of hypocotyl and radicle which normally extend from the incipient root primordium to the base of the cotyledonary primordia (compare Fig. 6G with 6C). The vascular primordium, which in the wild type consists of about 6 files of narrow cells, is absent, and a ‘central pile’ of fairly large, isodiametric cells protrudes from the upper end of the suspensor into the embryo (Fig. 6G,H). This ‘central pile’, which is often observed from the triangular stage on (not visible in Fig. 6F; see Fig. 6K,L), extends to the base of the cotyledonary primordia by the mid-torpedo stage, being about eight cells high (Fig. 6H). The origin of the ‘central pile’ could not definitively be established although its position and growth from the upper end of the suspensor suggest that it may have been produced by abnormal divisions of the uppermost suspensor cell.
The mutant torpedo-stage embryo shows normal growth and morphological differentiation in the cotyledonary primordia as compared to wild-type embryos of the same stage (compare Fig. 6H with 6D). In addition to the epidermis, derived from the outer layer of the early embryo, strands of narrow cells were found in the basal region of the cotyledonary primordia, and these cells seem to correspond to the primordia of the vascular strands. By contrast, wildtype and mutant embryos are markedly different in the basal region (Fig. 6D,H): the wild-type hypocotyl is enlarged and radially differentiated whereas the basal part of mp mutant embryo contains relatively few indistinct cells, indicating that little growth has occurred between the late-heart and mid-torpedo stages (Fig. 6G,H). The basal part of the mutant embryo gives rise to the ‘basal peg’.
A considerable proportion of mp mutant embryos do not undergo the symmetric development described above. At the early-heart stage, mp mutant embryos often show differential outgrowth of the two cotyledonary primordia (Fig. 6K) or seem to form only a single cotyledon (Fig. 6L). Distortion of symmetry was often observed in even younger mp mutant embryos, presumably due to oblique cell divisions in the basal part of the embryo (Fig. 6I). This early asymmetric development may be responsible for the variable arrangement of cotyledons (see Discussion).
In summary, mp mutant embryos appear to lack the information that is required for the specification of the lower tier of the octant-stage embryo and the adjacent hypophysis, resulting in abnormal patterns of cell division. Other processes such as the formation of the suspensor, the segregation of epidermal precursor cells or the outgrowth of cotyledonary primordia are apparently not affected.
Root formation by mp mutant tissue in culture
All mp mutant embryos, regardless of the allele studied, are incapable of forming the root and the root meristem. Mutant seedlings with the 10 strong alleles also invariably lack the hypocotyl, while 3 alleles classified as weak allow for the occasional formation of a short hypocotyl. Although these seedling phenotypes argue for the mp gene product organising the basal body region rather than being specifically involved in making the root, we directly tested whether root formation can be induced in mp mutant tissue by appropriate culture conditions. Due to the different seedling phenotypes of weak and strong alleles, two different procedures were applied.
Mutant seedlings with two of the weak alleles (mpG92 and mpU348) that had developed a short hypocotyl were subjected to a modification of the treatment described by Weiland and Müller (1972; see Materials and methods). Briefly, mutant seedlings were wounded at the level of the hypocotyl and cultured on an auxin-containing medium. Roots emerged from the wounded seedlings in 21 of 28 cases (75%) for allele mpG92 and in 7 of 17 cases (41%) for allele mpU348 (Fig. 7A,B). For comparison, bisected wild-type seedlings formed roots in 45 of 47 cases (96%). Thus, root formation can be induced in wounded seedlings that lack root and root meristem because of reduced mp gene activity in embryogenesis.
A more stringent test was performed with tissue from mp seedlings that were mutant for two presumed null alleles (mpS4 and mpU21). Pieces of tissue were dissected from mutant seedlings and cultured as described in Materials and methods. The tissue pieces were mostly of cotyledonary origin although a functional shoot meristem was sometimes included, and explants thus developed into plantlets or looked callus-like after four to six weeks in culture (Fig. 7CE). The appearance of the cultured tissue had no marked effect on root formation. Roots were observed in 14% (4 of 29) of the explants from allele mpS4 and in 24% (8 of 33) of the cases for allele mpU21. Thus, root formation can occur in mutant tissue that presumably lacks functional mp gene product.
DISCUSSION
Apical-basal pattern formation in the flowering plant embryo generates a reproducible sequence of seedling structures, including the meristems of the shoot and the root at opposite ends of the axis. The isolation of putative pattern mutants in Arabidopsis has led to the identification of a gene, monopteros (mp), that appears to be specifically required for the formation of basal body structures such as hypocotyl, radicle and root meristem (Mayer et al., 1991). We have now explored the role the mp gene may play in embryonic pattern formation. The findings indicate that the mp gene is primarily required for organising the basal region of the developing embryo from early on. The variable arrangement of cotyledons, as seen in mutant seedlings, seems to result indirectly from the lack of organised growth in the basal region.
Developmental basis for the deletion of basal pattern elements in mp seedlings
The mp seedling phenotype has been traced back to the early embryo in order to obtain clues as to the developmental process affected. mp mutant embryos show abnormalities as early as the octant stage. In contrast to the expectation that a basal deletion phenotype derives from a mutant embryo with fewer cells than wild-type, the mp embryo proper contains more cells than normal. However, these cells are not functionally equivalent to the lower tier of the wild-type embryo proper, as judged by the behaviour of their descendants.
The basal body structures that are deleted in mp seedlings normally derive from specific regions of the octant-stage embryo: the lower tier of the embryo proper and the uppermost suspensor cell (Schulz and Jensen, 1968; Tykarska, 1976, 1979; Mansfield and Briarty, 1991; Jürgens and Mayer, 1993). From the early-globular stage on, the descendants of those cells show specific patterns of cell division and cell elongation. mp mutant embryos seem to lack instructions for this organised, directional growth of the basal region. The descendants of the lower tier(s) show a random cell-division pattern, thus resembling the upper-tier descendants. Similarly, the uppermost suspensor cell does not establish the precisely ordered pattern of cell division that characterises the wild-type hypophysis. Since the ‘central pile’ of cells appears in place of the hypophyseal derivatives, it seems likely to us that the ‘central pile’ derives from the uppermost suspensor cell which, in this view, would continue to divide horizontally, as normal suspensor cells do. As this ‘central pile’ extends into the growing embryo, it is gradually ensheathed by adjacent cells derived from the mutant embryo proper, and this assemblage of cells later gives rise to the ‘basal peg’. Thus, the position of the early defect correlates well with the basal deletion of the seedling, and this correlation holds throughout embryogenesis.
mp gene activity is essential for directional growth in the basal region of the embryo which eventually gives rise to the root. By contrast, mp mutations do not interfere with the regenerative pathway of root formation that can be induced experimentally in various tissues (Smith and Murashige, 1970; Feldman, 1976; Feldman and Torrey, 1976; Schiavone and Racusen, 1991). Thus, the embryonic pathway of root formation seems to involve specific events that occur exclusively in the basal region of the embryo. As this region develops from two adjacent cell groups of different origin, the lower tier of the embryo proper and the hypophysis, organising the growth pattern may require their interaction. To this effect, the mp gene may be active in both cell groups. Alternatively, only one of the two may autonomously require mp gene product, with the other depending on instructions from the former. For example, the uppermost suspensor cell may normally become the hypophysis in response to some signal from the embryo proper, and the mp mutant embryo proper may fail to produce that signal. Such a scenerio would explain why the primary role of the mp gene is confined to embryogenesis. The embryo-specific requirement distinguishes the mp gene from another gene involved in apical-basal pattern formation, the gnom gene, which has recently been shown to be necessary for root formation in the embryo as well as in tissue culture (Mayer et al., 1993).
Origin of apical defects in mp mutant seedlings
The mp gene is not absolutely required for proper spatial arrangement of cotyledons as indicated by the large proportion of strong mp mutant seedlings showing normal cotyledon arrangement (see Table 2). In the absence of mp gene activity, the developmental process generating the arrangement of cotyledons seems to be labile, suggesting that a different mp-dependent process normally ensures that the cotyledonary primordia are established in their proper places. Our data as well as other observations make it very likely that the body axis plays this stabilising role.
The spatial arrangement of cotyledons is variable in mp mutant seedlings lacking a hypocotyl. Conversely, the cotyledons are properly spaced in mutant seedlings that have a hypocotyl, however short. This correlation also holds for other mutants. For example, mutations in other genes that result in seedlings with a short hypocotyl and no roots, do not affect the spacing of cotyledons (T. B., unpublished observation). By contrast, mutations in the fackel gene, which specifically affect the hypocotyl, result in abnormal arrangement of cotyledons (Mayer et al., 1991). Similarly, fass mutant seedlings have an abnormally wide hypocotyl, and this phenotype can be associated with supernumerary cotyledons (Mayer et al., 1991; R. A. Torres Ruiz and G. J., unpublished data). In these cases, the primary lesion seems to be in the seedling axis rather than in the cotyledons themselves.
Cotyledonary primordia become recognisable in the apical region of the early-heart stage embryo: two buttresses are symmetrically positioned with respect to the body axis which is formed by the derivatives of the lower tier (Schulz and Jensen, 1968; Tykarska, 1976, 1979; Mansfield and Briarty, 1991; Jürgens and Mayer, 1993). In early mp mutant embryos, an incipient body axis does not form as indicated by isodiametric cell shape and random cell-division patterns in the basal region. This failure frequently results in asymmetric shapes of globular embryos, and the cotyledonary primordia are thus often abnormally positioned at the earlyheart stage. In this way, the primary defect of mp mutant embryos, i.e. lack of organised basal growth, seems to result in the variable apical defect.
How the symmetric positioning of cotyledonary primordia is achieved in the wild-type embryo is not known. By analogy to the spacing of leaf primordia in which inhibitory interactions have been considered to play a role (Steeves and Sussex, 1989, and references therein), one might speculate that positioning of cotyledonary primordia also involves interaction. This idea receives support from mutations that specifically alter number or spacing of cotyledons, without obviously affecting the seedling axis (Jürgens et al., 1991, and unpublished observation). Mutually inhibitory influences have the inherent tendency to enhance initial asymmetries such as those seen in early mp mutant embryos, which would explain the large proportion of mp mutant seedlings with only a single cotyledon. This view implies a labile balance between the early cotyledonary primordia: proper spacing of cotyledons would thus be favoured if the primordia were initiated nearly simultaneously and symmetrically about the body axis. In mp mutant embryos, however, a body axis does not form, resulting in variable initiation of cotyledonary primordia whose fate would then be determined by their mutually inhibitory interaction.
mp mutant seedlings showed another apical defect, incomplete vascularisation of cotyledons, and this defect was strictly dependent on mp gene activity, in contrast to the spatial arrangement of cotyledons. All strong mp mutant seedling phenotypes invariably showed this trait while weaker seedling phenotypes tended towards normality. In individual mp seedlings of the latter class, there was no clear correlation between the basal pattern deletion and this apical defect, and their relationship, if any, is thus not obvious. One might consider the possibility that the mp gene product is required for two seemingly unrelated processes in embryogenesis. Such a redeployment of a developmental gene would not be without precedence as this has amply been documented for early-acting segmentation genes in Drosophila (Ingham, 1988).
Implications for apical-basal pattern formation
From the analysis of mutant phenotypes, we previously proposed that the apical-basal axis may initially be partitioned into regions (Mayer et al., 1991). Such regions may be established in the octant-stage embryo, with different cell groups giving rise to distinct parts of the apical-basal pattern. This notion seems to be supported by the early phenotype of mp mutant embryos: the defects are restricted to the basal cells of the embryo proper and the uppermost suspensor cell, whereas the apical cells of the embryo proper are not affected. The monopteros gene may thus be viewed as a region-specific patterning gene that directs development of contiguous cells originally defined by position in the octant-stage embryo. Within its domain of action, more mp gene activity seems to be required for the production of very basal structures, as the residual gene activity of weak alleles occasionally generates a short hypocotyl but not a root. This spatial difference may reflect different growth dynamics, influenced by continual mp gene activity.
A good candidate for a gene involved in early partitioning is gnom, as indicated by two observations (Mayer et al., 1993). First, the gnom gene is already required for the asymmetric division of the zygote. Second, gnom is epistatic to mp, indicating that gnom gene activity is a prerequisite for mp gene action. Genes like gnom may act transiently to confine the action of region-specific genes to their proper domains. Genes like mp may subsequently remain active for longer periods of time, directing the development of specific body regions. Such a mode of pattern formation would provide enough flexibility to account for diverse growth patterns as seen in early embryos from different flowering plant species (Rutishauser, 1969; Johri, 1984).
ACKNOWLEDGEMENTS
We thank Ulrike Mayer for establishing the histological techniques in the laboratory, Maarten Koornneef for providing W100 seeds, F. Assaad, M. Busch, T. Fischer, C. Hardtke, T. Laux, W. Lukowitz, U. Mayer, S. Miséra, S. Ploense and R. A. Torres Ruiz for helpful suggestions on the manuscript, and H. Jäckle for his generous support in the early phase of this project. This work was supported by grants Be 1374/1-1, Ju 179/2-1 and Ju 179/2-2 from the Deutsche Forschungsgemeinschaft