Genetically Induced Abnormalities in Drosophila: Two or Three Patterns?

SYNOPSIS. The removal of a portion of a Drosophila imaginaldisc stimulates pattern regulation whereby the missing portionis regenerated or extra copies of the surviving portion (duplicationsand triplications) are produced. The results of recent experimentsin which temperature-sensitive cell-lethal mutations were usedto induce pattern regulation are considered here in an attemptto answer a major question: What is the nature of the pattern-formingsystem in the newly formed tissues? One current hypothesis isthat the observed pattern regulation phenotypes are the resultof interactions between portions of a single pattern. The evidencefrom studies in which Drosophila genetic investigative techniqueswere applied to developing leg duplications indicate that initiationand growth of the duplicate are similar or identical to normaldevelopment in terms of cell number, growth rate and patternof cell lineage (compartments). This suggests that portionsof the genetic mechanism underlying normal development may bereactivated and used to control abnormal development. Leg triplicationsconsist of one complete set of leg structures and two partialsets arranged in a mirror symmetrical cuticular process. Theseprocesses either become more or less complete distally (theydiverge or converge, respectively) by the addition or deletionof structures at the lines of symmetry. Whether a particularprocess diverges or converges is related to its circumferentiallocation. These leg duplication and triplication phenotypescan be explained as the result of cell death in situ followedby interaction between the surviving portions of the originalleg pattern following the rules of the polar coordinate modelof positional information.     

Congenital tibial aplasia with preaxial polydactyly: soft tissue anatomy as a clue to teratogenesis

We performed preoperative arteriography and postamputation dissection on a human limb having complete tibial aplasia and preaxial polydactyly. The tibia was replaced by a tendinous band with an attached connective tissue mass. In the leg, the muscles were normal. Muscles usually arising from the tibia arose from the tendinous band, Intrinsic muscles of the foot were absent where skeletal elements were absent and there were supernumerary muscles where there were supernumerary skeletal elements. The tendinous insertions of the muscles that originated in the leg followed the skeletal pattern of the foot. The nerves were normally distributed with the exception that extra branches innervated the supernumerary toes. Both the anterior tibial and peroneal arteries were smaller than normal and progressively reduced in size as they coursed distally and could not be identified below the ankle. The dorsalis pedis artery was absent. The other arteries of the leg and foot were normal with the exception of extra branches supplying the supernumerary toes. The anatomy indicates that the foot is probably a double posterior duplication. Such a defect implies abnormal specification of the foot pattern due to a prespecification event. The tibial remnant with normal leg soft tissues indicates normal specification of the leg pattern and subsequent interruption of tibial morphogenesis due to a postspecification event. The presence of these different types of malformations in the same limb may seem to be contradictory. We suggest, however, that a single teratogenic event occurring at one moment in time could cause combined pre- and postspecification malformations. We further suggest that a diminished anterior tibial artery reduced the number of vessels available for collateral circulation and thus put the limb at risk for subsequent malformation.     

Characterisation of interstitial duplications and triplications of chromosome 15q11–q13

Chromosome 15 is frequently involved in the formation of structural rearrangements. We report the molecular characterisation of 16 independent interstitial duplications, including those of one individual who carried a duplication on both of her chromosomes 15, and three interstitial triplications of the Prader-Willi/Angelman syndrome critical region (PWACR). In all probands except one, the rearrangement was maternal in origin. In one family, the duplication was paternal in origin, yet appeared to segregate in a sibship of three with an abnormal phenotype that included developmental delay and a behavioural disorder. Ten duplications were familial, five de novo and one unknown. All 16 duplications, including two not visible by routine G-banding, were of an almost uniform size and shared the common deletion breakpoints of Prader-Willi syndrome and Angelman syndrome. Like deletions, the formation of duplications can occur in both male and female meiosis and involve both inter- and intrachromosomal events. This implies that at least some deletions and duplications are the reciprocal products of each other. We observed no instances of meiotic instability in the transmission of a duplication, although recombination within the PWACR occurred in two members of the same family between the normal and the duplicated chromosome 15 homologues. All three triplications arose de novo and included alleles from both maternal chromosomes 15. Triplication breakpoints were more variable and extended distally beyond the PWACR. The molecular characteristics of duplications and triplications suggest that they are formed by different mechanisms.     

Retinoic acid modifies positional memory in the anteroposterior axis of regenerating axolotl limbs

The effects of retinoic acid (RA) on anteroposterior (AP) positional memory of regenerating axolotl limbs were tested after removing the anterior or posterior half from the zeugopodium (lower arm or leg). RA (150 micrograms/g body wt) was injected into groups of animals bearing the following types of limbs: (1) anterior and posterior half zeugopodia grafted to the eyesocket and amputated distally 7 days later; (2) unamputated anterior and posterior half zeugopodia in situ; (3) double anterior and double posterior half zeugopodia amputated distally 7 days after their construction; (4) sham-operated zeugopodia amputated distally 7 days after operation. Controls consisted of these four groups injected with the retinoid solvent, dimethyl sulfoxide, or not injected. Control half zeugopodia grafted to the eyesocket regenerated no more than one or two digits. Control unamputated half zeugopodia in situ underwent partial or complete regeneration of the missing half from the proximal and midline wound surfaces exposed during construction of the half zeugopodia. Control double anterior and posterior zeugopodia both regenerated symmetrical, hypomorphic regenerates with 1-3 digits in the double anteriors and 1-6 digits in the double posteriors. Sham-operated controls regenerated normally. Regenerating anterior and posterior halves responded differently to RA. RA-treated anterior half zeugopodia in the eyesocket, and anterior half stumps adjacent to the unamputated posterior half zeugopodia in situ both produced regenerates that duplicated stump structures in the proximodistal axis and formed a complete and normal AP pattern. RA-treated double anterior zeugopodia regenerated proximodistal-duplicated pairs of mirror-imaged limbs, each with a complete and normal AP pattern. In contrast, half posterior zeugopodia in the eyesocket, the posterior half stumps of unamputated half anterior zeugopodia in situ, and double posterior zeugopodia all failed to regenerate. These results suggest that RA modifies positional memory in only one direction in the AP axis, posterior.     

Homologies of positional information in thoracic imaginal discs ofDrosophila melanogaster

Summary The regulative behavior of fragments of the imaginal discs of the wing and first leg was studied when these fragments were combined with fragments of other thoracic imaginal discs. A fragment of the wing disc which does not normally regenerate when cultured could be stimulated to regenerate by combination with certain fragments of the haltere disc. When combined with a haltere disc fragment thought to be homologous by the criteria of morphology and the pattern of homoeotic transformation, such stimulated intercalary regeneration was not observed. Combinations of first and second leg disc fragments showed that a lateral first leg fragment could be stimulated to regenerate medial structures when combined with a medial second leg disc fragment but not when combined with a lateral second leg disc fragment. Combinations of wing and second leg disc fragments showed that one fragment of the second leg disc is capable of stimulating regeneration from a wing disc fragment while another second leg disc fragment fails to stimulate such regeneration. It is suggested that absence of intercalary regeneration in combinations of fragments of different thoracic imaginal discs is a result of homology or identity of the positional information residing in the cells of the fragments. The pattern of correspondence of positional information revealed by this analysis is consistant with the pattern of homology determined by morphological observation and by analysis of the positional specificity of homoeotic transformation among serially homologous appendages. The implications of the existence of homologous positional information in wing and second leg discs which share a common cell lineage early in development are discussed.     

The role of cell death in the induction of pattern abnormalities in a cell-lethal mutation of drosophila

The effects of 48-hr 29°C temperature treatments on the imaginal leg discs of Drosophila hemizygous for a temperature-sensitive cell-lethal mutation were examined to determine whether the induction of patches of cell death in the imaginal discs is a prerequisite for the induction of pattern triplications. In a statistical analysis, the frequency of induction of cell death was found to be highly correlated with the frequency of induction of triplications. In addition, individual discs in which cell death had been induced were cultured and found to triplicate at frequencies significantly greater than discs with no visible cell death, or unselected discs from the same larvae.     

Autoregulative processes and structural principle of functional selective mobilization

Autoregulative systems are being formed through dynamical changeability of structural components. Initial structural organization determinates possible variants of regulative connections with different probabilities resulting in a more successful formation of one system and retarding in the appearance of another one. It emphasized the domination of structural principle of functional selective mobilization during the creation of physiological, pathological and ambivalent systems (having, accordingly, adaptive, disadaptive and ambivalent significance). That's why result of system activity has not a dominant role in the process of system formation (the result, if it has adaptive significance, only promotes the consolidation of previously formed regulative connections).     

The characteristics of osteogenesis under conditions of stretch tension]

Structure of rough-fibrillar, netted and laminated bone tissues, formed in distraction regenerates on various stages of leg lengthening, was studied experimentally on dogs, using light, transmission and scanning electron microscopy and electron probe microassay. It was ascertained, that the first two types of tissues belong to the category of provisory, rapidly renewing ones, the volume increase of which is possible not only at the expense of appositional growth but also interstitially. Their formation in the area of the regenerate, more proximally and more distally than the medial layer, provided longitudinal growth of primary osteons forming here and thereby the growth of the whole bone regenerate.     

Leg regeneration in insects. An experimental analysis in Drosophila and a new interpretation.

Fragments from prospective distal regions of Drosophila male foreleg imaginal discs failed to undergo proximal intercalary regeneration across leg segment borders when mechanically intermixed and cultured for 8 days with various fragments from prospective proximal disc regions. The failure of the distal cells to regenerate proximal leg segments was not due to a general restriction in their developmental potentials: Distal fragments, when deprived of their distal-most tips, regenerated in the distal direction at a high frequency. It is concluded that there exist in Drosophila leg discs the same restrictions with respect to regeneration along the proximodistal leg axis as had been previously observed in legs of several hemimetabolous insect species: Intersegmental discontinuities between grafted tissue pieces are not eliminated by intercalation. Based on the available evidence in hemimetabolous insects and in Drosophila, a new interpretation of the different aspects of regeneration in insect legs is offered. It is proposed that the two categories of regulative fields observed in insect legs, the leg segment fields and the whole leg field, represent the units of regulation for two fundamentally different regulative pathways that a cell at a wound edge can follow, the intercalative pathway and the terminal pathway, respectively. It is suggested that the criterion used by cells at healing wounds to choose between the two pathways is the difference in circumferential positional information between juxtaposed cells. The intercalative regulative pathway is switched on when cells with disparities in their axial positional information, or cells with less than maximal disparities in their circumferential information, contact one another. The terminal regulative pathway is triggered whenever cells with maximal circumferential disparities come into contact.     

Pattern regulation and regeneration

Insect legs develop from small regions of the embryonic thorax. In most insects they differentiate in the embryo, forming functional larval legs, which grow and moult through larval life. In Drosophila the presumptive legs invaginate to form imaginal discs, which grow through larval life but only differentiate in the pupal stage. Analysis of the structures formed after amputation, grafting and wounding experiments on larval legs and on mature and immature imaginal discs suggests that the same organization of positional information and cellular behaviour is involved in the response of tahe developing leg to disturbance at early stages (termed 'regulation') and at later stages (termed 'regeneration'). The results suggest that developing legs form pattern in accordance with positional information specified in two dimensions within the epidermis, along polar coordinates. A continuous sequence of positional values runs around the circumference and an independent sequence runs down the leg. Two rules govern cellular behaviour after a disturbance. The shortest intercalation rule: interaction between cells with different positional values provokes local growth, producing cells with intermediate values (by the shortest route in the case of the circumferential values). The distalization rule: if intercalated cells have positional values identical to those of adjacent pre-existing cells then the new cells adopt a more distal value. These rules will produce a complete distal regenerate from a complete circumference and may produce a symmetrical regenerate from a symmetrical wound surface. This regenerate may taper (converge) or widen (diverge) and branch into two distal tips, depending on the extent of the original wound and the way in which it heals. The polar coordinate model provides a simple and unified interpretation, in terms of only local interactions, of a wide range of experimentally produced and naturally occurring insect (and crustacean and amphibian) limbs showing regeneration of missing structures, duplication of structures, and the formation of complete, tapering or branching supernumeraries. It is not yet clear what molecular mechanisms could underlie a polar map of positional information, nor how such a map could be initially established at a particular site in the early embryo.     

Next-Generation Sequencing of Duplication CNVs Reveals that Most Are Tandem and Some Create Fusion Genes at Breakpoints

Interpreting the genomic and phenotypic consequences of copy-number variation (CNV) is essential to understanding the etiology of genetic disorders. Whereas deletion CNVs lead obviously to haploinsufficiency, duplications might cause disease through triplosensitivity, gene disruption, or gene fusion at breakpoints. The mutational spectrum of duplications has been studied at certain loci, and in some cases these copy-number gains are complex chromosome rearrangements involving triplications and/or inversions. However, the organization of clinically relevant duplications throughout the genome has yet to be investigated on a large scale. Here we fine-mapped 184 germline duplications (14.7 kb–25.3 Mb; median 532 kb) ascertained from individuals referred for diagnostic cytogenetics testing. We performed next-generation sequencing (NGS) and whole-genome sequencing (WGS) to sequence 130 breakpoints from 112 subjects with 119 CNVs and found that most (83%) were tandem duplications in direct orientation. The remainder were triplications embedded within duplications (8.4%), adjacent duplications (4.2%), insertional translocations (2.5%), or other complex rearrangements (1.7%). Moreover, we predicted six in-frame fusion genes at sequenced duplication breakpoints; four gene fusions were formed by tandem duplications, one by two interconnected duplications, and one by duplication inserted at another locus. These unique fusion genes could be related to clinical phenotypes and warrant further study. Although most duplications are positioned head-to-tail adjacent to the original locus, those that are inverted, triplicated, or inserted can disrupt or fuse genes in a manner that might not be predicted by conventional copy-number assays. Therefore, interpreting the genetic consequences of duplication CNVs requires breakpoint-level analysis.     

The investigation of the structure of collagen in growth process by X-ray analysis and electron microscopy

The structure of collagen in growth process has been investigated by X-ray analysis and electron microscopy using laying hen leg tendon collagen. On unstretching, the orientation of the band structure becomes better with age in birds younger than 4.5 months and is complete at ages above 4.5 months, whereas on stretching, the orientation is complete independent of age. This result suggests that the band structure may be complete by hatching. At approx. 4.5 months of age, the laying hen leg tendon collagen begins to harden from the lower end portion of the leg. On a macroscopic level, this hardening means that the collagen changes from the soft and flexible state to the rigid state. The higher-order structure of the hardened collagen consists of two domains: one is the domain in which the band structure remains, though it is not as clear as that of the collagen in the soft tendon, and another is the domain in which the band structure disappears and slender streaks having widths of 5-10 nm run along the fibril axis. It can be considered that this hardening might be caused by the increase of cross-links accompanied by calcification.     

Compartmental restrictions and blastema formation during pattern regulation in Drosophila imaginal leg discs

Clonal analysis was used to study the regulative behavior of cells in Drosophila imaginal leg discs. Such studies performed during normal development of the leg have revealed a clonal restriction known as the anterior-posterior compartment boundary (E. Steiner, 1976, Wilhelm Roux Arch. Entwicklungsmech. Organismen180, 9–30). When we tested a regulating fragment that contained cells from both anterior and posterior compartments this clonal restriction was maintained in the original fragment. However, in material produced by regulation, clones of cells induced at the time of fragmentation differentiated anterior and posterior structures. Clonal restriction was observed in the regulated material when clones were induced during in vivo culture. We deduced the position of the dividing cells that contributed to regulative growth from the positions of the clones within the differentiated disc tissue. We observed that initially the majority of dividing cells originated from and were localized to an area close to a region of the wound, resembling a blastema. As regulation proceeded, a localization of dividing cells was maintained. However, the blastema changed its position from the original material into the regulated part.     

Regeneration and duplication following operations in situ on the imaginal discs of Drosophila melanogaster

A technique is described which allows defects to be made in situ in the imaginal discs of immature Drosophila larvae. Bisection of the second leg disc across the upper-lower axis results in regeneration of the remainder of the disc from the upper portion, and mirror-image duplication of the anlagen in the lower half (Figs. 2–5, Table 1). The upper half, retaining its connection to the larval epidermis, is able to evert; the lower half metamorphoses as an uneverted implant. Partial bisection of the disc often results in the production of branched legs in which one branch is complete but the other is a double half (Figs. 7–9). These cases can be interpreted as resulting from regeneration from one cut surface and duplication from the other. Pattern triplications have been obtained by partial bisections of the wing disc (Fig. 10), and these can be interpreted in a similar manner. It is suggested that regeneration and duplication are identical phenomena, resulting from the properties of of the anlagen at the cut edge. Cases of regeneration and duplication in other insect and vertebrate systems are discussed, and interpreted on the basis of gradients of developmental capacity (Fig. 11).     

Evolution of predetermined germ cells in vertebrate embryos: implications for macroevolution

The germ line is established in animal embryos with the formation of primordial germ cells (PGCs), which give rise to gametes. Therefore, the need to form PGCs can act as a developmental constraint by inhibiting the evolution of embryonic patterning mechanisms that compromise their development. Conversely, events that stabilize the PGCs may liberate these constraints. Two modes of germ cell determination exist in animal embryos: (a) either PGCs are predetermined by the inheritance of germ cell determinants (germ plasm) or (b) PGCs are formed by inducing signals secreted by embryonic tissues (i.e., regulative determination). Surprisingly, among the major extant amphibian lineages, one mechanism is found in urodeles and the other in anurans. In anuran amphibians PGCs are predetermined by germ plasm; in urodele amphibians PGCs are formed by inducing signals. To determine which mechanism is ancestral to the tetrapod lineage and to understand the pattern of inheritance in higher vertebrates, we used a phylogenetic approach to analyze basic morphological processes in both groups and correlated these with mechanisms of germ cell determination. Our results indicate that regulative germ cell determination is a property of embryos retaining ancestral embryological processes, whereas predetermined germ cells are found in embryos with derived morphological traits. These correlations suggest that regulative germ cell formation is an important developmental constraint in vertebrate embryos, acting before the highly conserved pharyngula stage. Moreover, our analysis suggests that germ plasm has evolved independently in several lineages of vertebrate embryos.     

A modified walking rhythm employed during righting behavior in the cockroachGromphadorhina portentosa

Summary Electromyograms were recorded from leg muscles of the cockroachGromphadorhina during walking and righting under free-ranging and tethered conditions. Two muscles which are essentially synergistic during walking become antagonistic during righting (Fig. 3, 4). This explains in part the difference in the direction of the leg stroke in the two behaviors (Fig. 2). Other properties of the muscle activity are very similar during the two rhythms: the same motoneurons appear to be active (Fig. 5, 6); cycle frequencies are the same; the burst length of one motoneuron studied varies with burst frequency in a generally similar manner in both behaviors (Fig. 7); inter-leg coordination is the same (Fig. 9); and transganglionic coupling characteristic of walking can occur while a leg on one side is engaged in walking, and its contralateral homologue is engaged in righting (Fig. 10). Although other properties of the leg rhythms are different in walking and righting, these differences appear to result from dissimilarities in sensory feedback. It is concluded that although the two leg rhythms are superficially quite different, the underlying central neuronal rhythms are very similar, and possibly result from activity in the same central oscillatory cell or circuit.We thank Carol Smith for technical assistance. This work was supported by NIH grant #NS09083-05. Computation was done at the New York State Veterinary College Computer Facility which is supported by NIH grant RR 326.     

ELECTRON MICROSCOPY OF PHIALOCONIDIOGENESIS IN METARRHIZIUM ANISOPLIAE

Fine-structure observations with two different fixation procedures showed that phialide necks possessed a thickened electron-transparent wall layer. Phialoconidia developed from a wall layer which originated 1–1.5 μm within phialide necks. After conidium initials blew out of phialide tips and organelles entered, conidia were delimited by transverse septa which did not appear to be plugged by Woronin body-like plugs. Instead, septa appeared to become functionally complete by continued centripetal growth. Conidium-delimiting septa moved distally out of phialide necks as subsequent conidium initials formed. During this distal movement, septa increased in thickness and lamellae appeared on the conidium side; mature conidia had bipolarly lamellate cell walls. Conidial walls had a thin, ridged electron-dense outer wall layer and a thicker electron-transparent inner wall layer which increased in thickness centripetally after septum delimitation. Conidia were usually uninucleate and possessed conspicuous storage vacuoles with lipid and protein contents. Conidia also possessed numerous presumably lipid droplets. Multivesicular bodies were observed near conidium-delimiting septa and conidium walls which were increasing in thickness.     

Régulation des excédents dans le développement du bourgeon de membre de l'embryon d'oiseau. Analyse expérimentale de combinaisons xénoplastiques caille/poulet

Summary In order to support the demonstration of the regulative capacity of the chick limb bud, already stressed by one of us (Kieny, 1964, 1967), heterospecific combinations were made between chick and quail tissues, the cells of the latter bearing a distinctive nuclear marker. A Japanese quail whole limb bud (stage-18 to 21 of H. H., wing or leg) was grafted distally onto the prospective zeugopod of a chick (stage-22) wing bud sectioned at the prospective wrist level. Thus, from a heterospecific surplus recombinant containing five prospective limb segments (stylopod and zeugopod from the chick host; stylopod, zeugopod and autopod from the quail graft), it was possible to obtain a normally shaped appendage that comprised either upper arm, lower arm and hand in the case of a wing bud graft, or heteromorphic upper arm, lower leg and foot in the case of a hind-limb bud graft. In these cases, regulation for excess appeared to take place mainly within the host tissues. The three proximal segments of the recombinant, namely the chick stylopod and zeugopod of the host's stump and the quail stylopod of the graft, became reorganized and gave rise to a single stylopodial segment, which usually contained a double stylopodial bone element, one of chick, the other of quail origin.The absence of development of the squeezed prospective zeugopod can be interpreted as follows: owing to an interaction with the stylopodial graft tissues, the zeugopodial cells of the juxtaposed stump boundary have shifted proximally their originally more distal positional values, so that they changed their prospective pattern of differentiation to that of stylopod. These reset zeugopodial cells combine with the stylopodial cells of host and graft and form a huge composite stylopod, in which, due to an asynchronous determination in the two species, chick and quail tissues do not cooperate fully for the development of a single bone.

Ce travail a été effectué avec l'aide de la D.G.R.S.T. (Action complémentaire coordonnée: Biologie de la reproduction et du développement, convention n^o 73-7-1661)