Dynamic role of microvilli in peritrophic membrane formation

Although the peritrophic membrane (PM) is a common extracellular construction in many invertebrate groups, evidence of the location of its secretion has never been reported. In this study a specific marker for chitin has been developed, enabling a separate examination of secretion of the chitinous and proteinaceous components of the PM in the millipede, Glomeris marginata. Chitin appears first at the base of the microvilli (MV), synchronized in adjacent cells along the entire length of the midgut. Evidence showing that it originates at the plasma membrane is discussed. Proteinaceous components appear to be added from the MV to the chitinous sheet as it moves along the MV toward the lumen. Precedence for such a dynamic role for MV in formation of extracellular structures is reviewed. The completed PM extends around individual items in the gut contents as well as forming a multilayered envelope; this may enhance both its digestive and protective functions.     

A pattern formation mechanism to control spatial organization in the embryo of Drosophila melanogaster

It is known that cells are already committed to a particular segment at the cellular blastoderm stage during embryogenesis of Drosophila melanogaster. Recently, several segmentation genes have been observed to be expressed in a sequence of banded spatial patterns in the syncytial blastoderm, prior to the formation of the cellular blastoderm. It is demonstrated in this paper that a two component reaction-diffusion (RD) system with net production functions which are antisymmetric with respect to the uniform steady-state values, is capable of producing a sequence of seven spatial patterns in the syncytial blastoderm. The sequence of patterns obtained exhibit a strong preference for banded or striped patterns. The first pattern is a simple anteroposterior gradient while the second is a gradient in the dorsoventral direction. The next five patterns are a sequence of banded patterns which exhibit frequency doubling, i.e. the number of bands in each pattern tend to be double the number in the previous pattern. The predicted pattern sequence is comparable to that observed in the expression of some segmentation genes. It is suggested that a pattern formation mechanism based on such an RD system may exist in the embryo where it produces a sequence of prepatterns to regulate the expression of various segmentation genes leading ultimately to a segmented embryo. There is sufficient spatial information in the sequence of banded prepatterns for the segments to be unique.     

Cellular mechanisms governing synaptic development in Drosophila melanogaster

The neuromuscular connections of Drosophila are ideally suited for studying synaptic function and development. Hypotheses about cell recognition can be tested in a simple array of pre-and postsynaptic elements. Drosophila muscle fibers are multiply innervated by individually identifiable motoneurons. The neurons express several synaptic cotransmitters, including glutamate, proctolin, and octopamine, and are specialized by their synaptic morphology, neurotransmitters, and connectivity. During larval development the initial motoneuron endings grow extensively over the surface of the muscle fibers, and differentiate synaptic boutons of characteristic morphology. While considerable growth occurs postembryonically, the initial wiring of motoneurons to muscle fibers is accomplished during mid-to-late embryogenesis (stages 15–17). Efferent growth cones sample multiple muscle fibers with rapidly moving filopodia. Upon reaching their target muscle fibers, the growth cones rapidly differentiate into synaptic contacts whose morphology prefigures that of the larval junction. Mismatch experiments show that growth cones recognize specific muscle fibers, and can do so when the surrounding musculature is radically altered. However, when denied their normal targets, motoneurons can establish functional synapses on alternate muscle fibers. Blocking synaptic activity with either injected toxins or ion channel mutants does not derange synaptogenesis, but may influence the number of motor ending processes. The molecular mechanisms governing cellular recognition during synaptogenesis remain to be identified. However, several cell surface glycoproteins known to mediate cellular adhesion events in vitro are expressed by the developing synapses. Furthermore, enhancer detector lines have identified genes with expression restricted to small subsets of muscle fibers and /or motoneurons during the period of synaptogenesis. These observations suggest that in Drosophila a mechanism of target chemoaffinity may be involved in the genesis of stereotypic synaptic wiring. © 1993 John Wiley & Sons, Inc.     

Cuticle formation in the embryo of Drosophila melanogaster

In Drosophila melanogaster embryos cuticle formation occurs between 12 and 16 hours of development at 25°C. The formation of the cuticulin and the protein epicuticular layers is simultaneous in the hypoderm, the tracheoblasts, and the fore- and hindgut cells. The cuticulin forms as a dual lamina, aggregating from granules secreted by the hypodermal cells. This is followed by the formation of a granular protein epicuticle and finally by the secretion of a mixed fibrous and granular endocuticle. All secretory cells are relatively simple in their ultrastructure. The secretory process is a membrane phenomenon, occurring at the tips of hypodermal microvillae on cells at the surface of the embryo and on those hypodermal cells lining the lumen of the fore- and hindgut. It also occurs along the entire surface of the tracheoblast lumen as well as on the outer surface of those cells which form exoskeletal chitinous setae. The process involves a specialization of the plasma membrane with the formation of secretory granules intracellularly beneath the membrane and the extrusion of these granules through the membrane to the outside where final cuticle formation occurs.     

Molecular organization of the cut locus of Drosophila melanogaster

Mutations of the cut locus (ct) of Drosophila can be divided into four groups based on their phenotypes and complementation patterns. Each group alters the phenotype of a different set of tissues. Two hundred kilobases of ct DNA, located in 7B1-2, have been cloned by chromosomal walking, and the cloned sequences have been used to analyze more than 40 mutants. Based on the location of transposable element mutations and the extent of deficiencies and an inversion, four cut locus regions can be defined. Mutations in each region affect the phenotype of a different set of tissues. The most centromere proximal region contains mutations that are null for cut locus function. Within individual regions, a higher level of organization can be detected.     

Localization and partial characterization of acyltransferases present during rapid membrane formation in the Drosophila melanogaster embryo

Rapid membrane assembly occurs in the early, syncytial Drosophila embryo when 3500 cells are separated within a period of 90 min by the formation of plasma membranes. Acyltransferases catalyzing two of the early steps in phospholipid synthesis were studied during the course of this membrane formation. The enzymes appeared to be similar to mammalian acyltransferases in pH and substrate optima. The activity was inhibited by sulfhydryl-binding reagents and stimulated by low concentrations of magnesium, calcium, and managnese. The enzymes incorporated α-l-glycerophosphate and palmityl coenzyme A into both phospholipids and neutral lipids. The acyltransferases were also localized cytochemically under conditions shown to preserve a substantial proportion of the enzyme activity. Early in embryo development, the activity was localized in the rough endoplasmic reticulum and nuclear envelope. Reaction products were particularly frequent around mitotic nuclei. During the first phase of plasma membrane formation, the activity was localized at the furrow regions of the plasma membrane and in the apical nuclear envelope. During the second (fast) phase, the reaction products appeared mainly in the basal nuclear envelope and rough endoplasmic reticulum internal to the nuclear layer. The data were consistent with the hypothesis that phospholipids for membrane assembly can be formed in situ in several subcellular compartments.     

Structural organization and diversification of Y-linked sequences comprising Su(Ste) genes in Drosophila melanogaster.

Expression of the X-linked repeated Stellate (Ste) genes, which code for a protein with 38% similarity to the beta-subunit of casein kinase II, is suppressed by the Su(Ste) locus on the Y chromosome. The structure and evolution of the Y-linked repeats in the region of the Su(Ste) locus were studied. The 2800 bp repeats consist of three main elements: the region of homology to the Ste genes, an adjacent AT-rich, Y-specific segment, and mobile element 1360 inserted in the Ste sequence. Amplification of repeats was followed by point mutations, deletions, and insertions of mobile elements. DNA sequencing shows that these repeats may be considered as Ste pseudogenes or as damaged variants of a putative gene(s) encoding a protein quite different from the Ste protein as a result of an alternative splicing pattern. A comparison of 5 variants of the Y-Su(Ste) repeats shows a number of recombination events between amplified and diverged sequences that could be due to either multiple unequal mitotic sister-chromatid exchanges or to gene conversion. It is a first demonstration on a molecular level of these processes occurring in heterochromatic non-rDNA tandemly organized sequences in an eukaryotic genome.     

Genomic organization of gypsy chromatin insulators in Drosophila melanogaster

Chromatin insulators have been implicated in the regulation of higher-order chromatin structure and may function to compartmentalize the eukaryotic genome into independent domains of gene expression. To test this possibility, we used biochemical and computational approaches to identify gypsy-like genomic-binding sites for the Suppressor of Hairy-wing [Su(Hw)] protein, a component of the gypsy insulator. EMSA and FISH analyses suggest that these are genuine Su(Hw)-binding sites. In addition, functional tests indicate that genomic Su(Hw)-binding sites can inhibit enhancer-promoter interactions and thus function as bona fide insulators. The insulator strength is dependent on the genomic location of the transgene and the number of Su(Hw)-binding sites, with clusters of two to three sites showing a stronger effect than individual sites. These clusters of Su(Hw)-binding sites are located mostly in intergenic regions or in introns of large genes, an arrangement that fits well with their proposed role in the formation of chromatin domains. Taken together, these data suggest that genomic gypsy-like insulators may provide a means for the compartmentalization of the genome within the nucleus.     

Ribosomal DNA organization before and after magnification in Drosophila melanogaster

In all eukaryotes, the ribosomal RNA genes are stably inherited redundant elements. In Drosophila melanogaster, the presence of a Ybb(-) chromosome in males, or the maternal presence of the Ribosomal exchange (Rex) element, induces magnification: a heritable increase of rDNA copy number. To date, several alternative classes of mechanisms have been proposed for magnification: in situ replication or extra-chromosomal replication, either of which might act on short or extended strings of rDNA units, or unequal sister chromatid exchange. To eliminate some of these hypotheses, none of which has been clearly proven, we examined molecular-variant composition and compared genetic maps of the rDNA in the bb(2) mutant and in some magnified bb(+) alleles. The genetic markers used are molecular-length variants of IGS sequences and of R1 and R2 mobile elements present in many 28S sequences. Direct comparison of PCR products does not reveal any particularly intensified electrophoretic bands in magnified alleles compared to the nonmagnified bb(2) allele. Hence, the increase of rDNA copy number is diluted among multiple variants. We can therefore reject mechanisms of magnification based on multiple rounds of replication of short strings. Moreover, we find no changes of marker order when pre- and postmagnification maps are compared. Thus, we can further restrict the possible mechanisms to two: replication in situ of an extended string of rDNA units or unequal exchange between sister chromatids.     

Sequence replication and banding organization in the polytene chromosomes of Drosophila melanogaster

The relative proportions of cloned DNA fragments from all known hierarchies of sequence organization in polytene and diploid chromosomes were compared. It was found that unique sequences of varying sizes and chromosomal locations are equally replicated in salivary gland chromosomes. Sequences of euchromatic polydisperse gene families are also replicated proportionately in polytene and diploid tissues. Perhaps the most significant finding is that the histone gene repeats, despite their normal banding organization, are under-replicated in the polytene chromosome of Drosophila melanogaster. However, the clustered and well-banded 5S genes are most likely equally replicated. It is therefore concluded that differential sequence replication plays no apparent role in either the assembly or morphology of a band; and likewise, the assembly of polytenic DNA into band units is not affected by either the local abundancy or arrangement of middle repetitive sequences. The likelihood that the clustered arrangement is an important factor in the selection of sequences for under-replication is discussed.     

The origin and functions of the insect peritrophic membrane and peritrophic gel

There is a a fluid (peritrophic gel) or membranous (peritrophic membrane, PM) film surrounding the food bolus in most insects. The PM is composed of chitin and proteins, of which peritrophins are the most important. It is proposed here that, during evolution, midgut cells initially synthesized chitin and peritrophins derived from mucins by acquiring chitin-binding domains, thus permitting the formation of PM. Since PM compartmentalizes the midgut, new physiological roles were added to those of the ancestral mucus (protection against abrasion and microorganism invasion). These new roles are reviewed in the light of data on PM permeability and on enzyme compartmentalization, fluid fluxes, and ultrastructure of the midgut. The importance of the new roles in relation to those of protection is evaluated from data obtained with insects having disrupted PM. Finally, there is growing evidence suggesting that a peritrophic gel occurs when a highly permeable peritrophic structure is necessary or when chitin-binding molecules or chitinase are present in food.