Wavelike isomorphic prepatterns in development

The patterns generated by these mechanisms are usually wavelike spatial patterns in the distribution of the chemical components and/or physical properties of the organism or tissue being considered. In this paper the range of patterns generated by one of these mechanisms, namely the reaction-diffusion (RD) system (Turing, 1952), is reviewed and its potential to function as a source of isomorphic prepatterns for the regulation of development in a wide range of organisms is illustrated. Examples have been chosen to show the capacity of an RD system to generate a single stationary spatial prepattern, as well as a travelling wavelike spatial prepattern. However, the full potential of an RD system to regulate development stems from its capacity to spontaneously generate a temporal sequence of isomorphic stationary wavelike spatial prepatterns, rather than just a single isomorphic stationary spatial prepattern. To demonstrate this point the examples presented include the morphogenesis of the skin and some of its appendages, as well as the early decisions in the embryogenesis of Drosophila leading to segmentation. The mini-review begins by comparing the concepts of positional information and a temporal sequence of isomorphic prepatterns, which represent two quite different approaches to understanding the spatial and temporal regulation of cellular differentiation.     

Pair-rule and gap gene mutants in the flour beetle Tribolium castaneum

 Early pattern formation in the Drosophila embryo occurs in a syncytial blastoderm where communication between nuclei is unimpeded by cell walls. During the development of other insects, similar gene expression patterns are generated in a cellular environment. In Tribolium, for instance, pair-rule stripes are transiently expressed near the posterior end of the growing germ band. To elucidate how pattern formation in such a situation deviates from that of Drosophila, functional data about the genes involved are essential. In a genetic screen for Tribolium mutants affecting the larval cuticle pattern, we isolated 4 mutants (from a total of 30) which disrupt segmentation in the thorax and abdomen. Two of these mutants display clear pair-rule phenotypes. This demonstrates that not only the expression, but also the function of pair-rule genes in this short-germ insect is in principle similar to Drosophila. The other two mutants appear to identify gap genes. They provide the first evidence for the involvement of gap genes in abdominal segmentation of short-germ embryos. However, significant differences between the phenotypes of these mutants and those of known Drosophila gap mutants exist which indicates that evolutionary changes occurred in either the regulation or action of these genes. Received: 8 May 1998 / Accepted: 17 June 1998     

Maternal-effect genes that alter the fate map of the Drosophila blastoderm embryo

The pattern of segmentation in the Drosophila embryo is controlled by at least 25 zygotically active genes and at least 20 maternally active genes. We have examined the pattern of expression of the protein product of the zygotically active segmentation gene fushi tarazu (ftz) at the cellular blastoderm stage in progeny of mutant females homozygous for each of six maternal-effect segmentation genes to observe the early effects of the maternal-effect genes on zygotic gene expression. The genes included exuperantia (a member of the anterior class of maternal-effect segmentation genes); staufen and vasa (members of the posterior class); and torso, trunk, and fs(1)N (members of the terminal class). Mutations in the genes caused a disruption of the normal pattern of ftz stripes in regions of the embryo where gene activity is known to be required. The ftz stripes provide a marker for segmental determination at the cellular blastoderm stage, making it possible to correlate aberrant patterns of ftz protein with defects in cuticle morphology at the end of embryogenesis. ftz protein expression in progeny of females mutant for combinations of the above genes was also examined. The changes in the ftz pattern in progeny of females doubly mutant for genes of the anterior and terminal classes or of the posterior and terminal classes can largely be understood as the result of the additive effects of the single mutations. In contrast, clearly nonadditive effects on the ftz pattern were seen when a mutation in a gene of the anterior class (exuperantia) was combined with mutations in posterior class genes.     

Theoretical aspects of stripe formation in relation to Drosophila segmentation

Many aspects of Drosophila segmentation can be discussed in one-dimensional terms as a linear pattern of repeated elements or cell states. But the initial metameric pattern seen in the expression of pair-rule genes is fully two-dimensional, i.e. a pattern of stripes. Several lines of evidence suggest a kinetic mechanism acting globally during the syncytial blastoderm stage may be responsible for generating this pattern. The requirement that the mechanism should produce stripes, not spots or some other periodic pattern, imposes preconditions on this act, namely (1) sharp anterior and posterior boundaries that delimit the pattern-forming region, and (2) an axial asymmetrizing influence in the form of an anteroposterior gradient. Models for Drosophila segmentation generally rely on the gradient to provide positional information in the form of concentration thresholds that cue downstream elements of a hierarchical control system. This imposes restrictions on how such models cope with experimental disturbances to the gradient. A shallower gradient, for example, means fewer pattern elements. This need not be the case if the gradient acts through a kinetic mechanism like reaction-diffusion that involves the whole system. It is then the overall direction of the gradient that is important rather than specific concentration values.(ABSTRACT TRUNCATED AT 250 WORDS)     

Developmental analysis of the torso-like phenotype in Drosophila produced by a maternal-effect locus

The segmental plan of the Drosophila embryo is already established at the blastoderm stage through the action of maternal effect genes which determine the polarity of the embryo and zygotically active genes involved in segmentation. We have analyzed the first example of a group of maternally acting genes which are necessary for establishing the developmental potential of the posterior 25% of the blastoderm. Females, homozygous for the X-linked maternal-effect mutation female sterile(1)Nasrat211 [fs(1)N211], produce embryos, characterized as torso-like, which lack all posterior endodermal derivatives as well as structures characteristic of abdominal segments 8 to 10. In addition, anterior endodermal derivatives are deficient and the absence of pharyngeal musculature causes a collapse of the cephalopharyngeal apparatus. The columnar blastoderm cell layer is defective at the posterior tip below the pole cells in these embryos. This defect, however, is presumably secondary to some abnormal feature of pole cell formation since in double mutants of fs(1)Nasrat211; tudor3 the blastoderm is normal but the embryos still show the torso-like phenotype. In situ hybridization with RNA probes derived from the fushi tarazu gene establishes that the cellular determination of the posterior blastoderm of embryos produced by fs(1)N211 is changed. This represents the first direct demonstration that a maternal-effect mutation alters the spatial distribution of a zygotic gene product involved in the segmental patterning of the embryo.     

Breakdown of abdominal patterning in the Tribolium Kruppel mutant jaws

During Drosophila segmentation, gap genes function as short-range gradients that determine the boundaries of pair-rule stripes. A classical example is Drosophila Krüppel (Dm'Kr) which is expressed in the middle of the syncytial blastoderm embryo. Patterning defects in Dm'Kr mutants are centred symmetrically around its bell-shaped expression profile. We have analysed the role of Krüppel in the short-germ beetle Tribolium castaneum where the pair-rule stripes corresponding to the 10 abdominal segments arise during growth stages subsequent to the blastoderm. We show that the previously described mutation jaws is an amorphic Tc'Kr allele. Pair-rule gene expression in the blastoderm is affected neither in the amorphic mutant nor in Tc'Kr RNAi embryos. Only during subsequent growth of the germ band does pair-rule patterning become disrupted. However, only segments arising posterior to the Tc'Kr expression domain are affected, i.e. the deletion profile is asymmetric relative to the expression domain. Moreover, stripe formation does not recover in posterior abdominal segments, i.e. the Tc'Kr(jaws) phenotype does not constitute a gap in segment formation but results from a breakdown of segmentation past the 5th eve stripe. Alteration of pair-rule gene expression in Tc'Kr(jaws) mutants does not suggest a direct role of Tc'Kr in defining specific stripe boundaries as in Drosophila. Together, these findings show that the segmentation function of Krüppel in this short-germ insect is fundamentally different from its role in the long-germ embryo of Drosophila. The role of Tc'Kr in Hox gene regulation, however, is in better accordance to the Drosophila paradigm.     

Regionalisation of segment-forming capacities during early embryogenesis inDrosophila melanogaster

Summary Transverse fragmentation of the egg ofDrosophila melanogaster results in the formation of partial larvae. Anterior and posterior egg fragments develop the respective partial larval patterns. The partial patterns do not add up to the complete pattern.Fragmentation near the middle of the egg during early cleavage causes a gap of 3–4 segments on average in the larva. This gap is reduced to 2 segments on average if operations are performed at the early syncytial blastoderm stage. Fragmentation near the pole regions from early cleavage stages onwards causes a gap of only 2 larval segments on average. When the egg is fragmented at the columnar cellular blastoderm stage or later, the gap at all positions amounts to the size of one segment or less. A gap is also found after incomplete fragmentation, when the ooplasmic bridge between both egg parts was constricted beyond a certain limit.A specific shift of the segment-forming capacities along the egg axis is observed from syncytial blastoderm stages onwards.After partial longitudinal fragmentation no additional structures are observed. In general, the partial transverse patterns add up to the complete pattern, but minor structures like single denticles are missing near the fragmentation site.The results are discussed with respect to current concepts of segment pattern formation during early embryogenesis in dipterans.     

The Drosophila membrane receptor Toll can function to promote cellular adhesion.

The product of the Toll gene is a membrane protein required for the formation of dorso-ventral polarity during early embryogenesis in Drosophila melanogaster. It acts together with the other dorsal group gene products to specify a nuclear gradient of dorsal morphogen in the syncytial blastoderm stage embryo. Here we report the presence in Toll protein of additional sequences held in common with the human membrane receptor platelet glycoprotein 1b (Gp1b). We propose that these sequences in Toll form disulphide linked extracellular domains that are important for the binding of ligands in the perivitelline space of the embryo. In addition, we show that expression of Toll protein induced in a non-adhesive cell line promotes cellular adhesion, a property held in common with the related Drosophila glycoprotein chaoptin. Toll protein in such aggregates accumulates at sites of cell-cell interaction, a characteristic displayed by other cellular adhesion molecules. Taken together these findings suggest that the biochemical function of Toll protein is more closely analogous to that of Gp1b than previously thought.     

Comparison of the gap segmentation gene hunchback between Drosophila melanogaster and Drosophila virilis reveals novel modes of evolutionary change.

We have cloned and sequenced a large portion of the hunchback (hb) locus from Drosophila virilis. Comparison with the Drosophila melanogaster hb sequence shows multiple strong homologies in the upstream and downstream regions of the gene, including most of the known functional parts. The coding sequence is highly conserved within the presumptive DNA-binding finger regions, but more diverged outside of them. The regions of high divergence are correlated with regions which are rich in short direct repeats (regions of high 'cryptic simplicity'), suggesting a significant influence of slippage-like mechanisms in the evolutionary divergence of the two genes. Staining of early D.virilis embryos with an hb antibody reveals conserved and divergent features of the spatial expression pattern at blastoderm stage. It appears that the basic expression pattern, which serves as the gap gene function of hb, is conserved, while certain secondary expression patterns, which have separate functions for the segmentation process, are partly diverged. Thus, both slippage driven mutations in the coding region, which are likely to occur at higher rates than point mutations and the evolutionary divergence of secondary expression patterns may contribute to the evolution of regulatory genes.