Autonomous puffing patterns in thoracic and abdominal polytene bristle cell chromosomes of the flesh fly Sarcophaga barbata

The puffing patterns of the thoracic and abdominal polytene bristle cell chromosomes were investigated in Sarcophaga barbata during a 10-day period of pupal development. The autonomous differentiation of imaginal disk descendants is visualized microscopically at the chromosomal level by the cell autonomous puff activities of the polytene bristle cell chromosomes. The sequence of chromosomal activities is strictly stage specific in both cell types. The changes in the puffing pattern are closely corelated with development. The puffing pattern changes synchronously in all bristle cells of a certain body region, e.g., the scutellum or the fifth abdominal tergit. However, there is no synchrony between the puffing pattern changes of the thoracic and abdominal bristle cells. The loci of the abdominal bristle cells are activated one day later than those of the thoracic cells. Each particular puffing pattern truly represents a particular developmental state of the bristle, regardless of body location. That is, the bristle cell chromosomes of various body segments control the timing of their puffing activities autonomously and puff formation and puff regression are not hormonally synchronized.     

Die Polytänchromosomen der Borstenbildungszellen von Calliphora erythrocephala

The apparatus forming bristles (macrochaetae) of Calliphora erythrocephala directly involves only two cells, of which the larger one, known as the triehogen cell, produces the long tapering hair, and the smaller tormogen cell forms a circular chitineous socket around the base of the bristle. During the development in the pupa these two cells proceed to grow rapidly by endomitotic polyploidisation, attaining a nuclear volume of about three thousand times that of the neighbouring epidermal cells. Under optimal culture conditions (especially of temperature and feeding) the chromosomes assume polytenic banded form in surprising good quality (Fig. 5c and 6). The chromosomes of the trichogen cells are subject of the investigations presented in this paper. — High fragmentation and unspecific fusing tendency — characteristic of larval polytene chromosomes of Calyptratae — are diminuished sufficiently to establish chromosome-maps (Tables I and II). Several definitive chromosome loci still retain a high rate of breakage. Some morphological properties of the chromosomes, especially the distribution of heterochromatin and the peculiar swollen kinetochore regions (Fig. 12b) have been described in more detail. Homologous pairing is distinctly reduced. The distribution of the pairing-gaps is non-random (Fig. 18, 20 and 21), but no correlation with other structural or functional properties of the chromosomes besides the sex dimorphismus in chromosome III (Fig. 22 and 23) is recognizable. Chromosome III is the sex chromosome pair. The only morphological difference between X- and Y-chromosome is an unilocal structural heterozygozity represented by a single additional intercalary heterochromatic band, which marks the Y-chromosome (Fig. 22 and 25). — The developmental history of the big puffs and Balbiani-rings I, III and IV has been followed over a period from the fifth to the eleventh pupal day. The majority of activated structures becomes inactivated in close correlation with the diminuition of ecdyson concentration in pupal haemolymph occurring with increasing age (as determined by Shaaya and Karlson, 1964). It is concluded, as a working hypothesis, that at least some of these puffs are under direct hormonal control of ecdyson. A smaller group of puffs attains maximal activation at a time, when ecdyson concentration has already decreased.     

Chromosomal control of foot pad development in Sarcophaga bullata

The puffing schedule of 71 puffs of chromosome B in Sarcophaga bullata polytene foot pad cells were analyzed during an 8 day period of pupal development. The number of puffs fluctuates, with maxima at about day 7 and day 10. The nucleolar volume reaches two maxima which precede the maxima in the number of puffs by approximately one day. With respect to qualitative changes in the puffing pattern, the present study shows that all puffs appear and disappear in a sequential fashion which is related to development. The pattern of potentially active loci and the sequence in which they form puffs are identical in all foot pad cells. Nevertheless, two neighboring cells may differ characteristically in the timing of the activity of a few individual loci relative to the rest of the puffing sequence. Furthermore, pulvilli cells from different pairs of legs may differ in the timing of the entire puffing sequence. It is concluded that puffing, at least in part, is under the control of intracellular processes rather than of external factors such as hormones.     

An overview of gene activity in the fat body of Drosophila gibberosa

In the larval fat body of Drosophila gibberosa, polytene chromosome structure and activity exhibit cytological differences from chromosomes of midgut and salivary glands. These differences include long-persisting puffs, transient puffs and long-persisting band modulations. Some early ecdysteroid-induced puffs are present in all three organs but few late puffs are present in the fat body. Comparative studies reveal, therefore, that late larval-early pupal puffing is enhanced in salivary glands relative to gut, fat body and Malpighian tubules. After the fat body breaks up in the prepupa, the rate of programmed cell death and the corresponding slow decline of chromosomal activity also differ from cell to cell and from other organs.by M.L. Pardue     

Veränderungen im Puffmuster und das Wachstum der Riesenchromosomen in Speicheldrüsen von Drosophila melanogaster aus spätlarvalen und embryonalen Spendern nach Kultur in vivo

Salivary glands from late third instar larvae of Drosophila melanogaster were transplanted into the abdomens of adult female and male flies and were kept in this medium from 6 to 120 h. Changes in the puffing pattern of chromosome arm III L were studied after the culture in vivo. Two noticeable puffs are induced. They are located in 68 B and 78 E. Neither of these loci show activity during normal development. — Front halves of embryos (6 to 9 h of age) were also transferred into adults. After 5 to 13 days in vivo they are able to develop and differentiate larval structures. Salivary glands, imaginal discs, fat body, Malpighian tubules and muscle fibers could be identified. Even 4 h old embryos can form polytene salivary gland chromosomes after a 13 day culture. These chromosomes can reach sizes comparable with the maximal size in normal development. In some nuclei an extensive growth leads to “supergiant” chromosomes. The puffs in 68B and 78E are formed in the polytenic chromosomes from embryonic implants as in cultured larval salivary gland chromosomes.     

Ultrastructure of the chemosensitive basiconic single-walled wall-pore sensilla on the antennae in adults and embryonic stages of Locusta migratoria L. (Insecta,Orthoptera)

Summary The structure and embryonic development of the two types (A, B) of basiconic sensilla on the antennae of Locusta migratoria were studied in material that had been cryofixed and freeze-substituted, or chemically fixed and dehydrated. Both types are single-walled wall-pore sensilla. Type-A sensilla comprise 20–30 sensory and 7 enveloping cells. One enveloping cell (thecogen cell secretes the dendrite sheath); four are trichogen cells, projections of which form the trichogen process during the 2nd embryonic molt. The trichogen cells form two concentric pairs proximally. Two tormogen cells secrete the cuticular socket of the sensillum. The dendritic outer segments of the sensory cells are branched. Bifurcate type-A sensilla have also been observed. Type-B sensilla comprise three sensory and four enveloping cells (one thecogen, two trichogen and one tormogen). The trichogen process is formed by the two trichogen cells, each of which gives rise to two projections. The trichogen cells are concentrically arranged. The dendritic outer segments of the sensory cells are unbranched. In the fully developed sensillum, all trichogen and tormogen cells border on the outer receptor lymph cavity. It is suggested that the multicellular organization of the type-A sensilla can be regarded as being advanced rather than primitive.Supported by the Dcutschc Forschungsgemeinschaft (SFB 4/G1)     

The effect of prolonged exposure to heat on the activity of salivary gland polytene chromosomes]

The influence of long-term heating on the puffing activity of polytene chromosomes in the early prepupa salivary glands was investigated. The activity of puffs was estimated by two criteria: size and frequency. The rearing of insects at a temperature of 29 degrees resulted in puff changes: the activity of some puffs increased or depressed, some puffs were inhibited, other puffs were induced newly. The differential response of each chromosome was observed. A possible mechanism of the effect of heating on the puff activity of polytene chromosomes is discussed.     

Polytene chromosomes of the Old World screwworm fly (Chrysomya bezziana) and its evolutionary relationships with Lucilia cuprina and Cochliomyia hominivorax (Diptera: Calliphoridae).

Standard polytene chromosome maps for the Old World screwsworm fly, Chrysomya bezziana, are presented. Good quality polytene chromosomes obtainable from pupal trichogen cells allow detailed analysis of autosomal euchromatin. The sex chromosomes are represented by irregular heterochromatic structures resembling those described previously in trichogen polytene chromosomes of the Australian sheep blowfly, Lucilia cuprina. A high degree of homology with the banding pattern of L. cuprina polytene chromosomes allowed direct recognition of approximately 60% of the L. cuprina complement in the C. bezziana maps. A further 13% may be homologous. The extensive homology observed is discussed in relation to the rate of chromosome rearrangement and conservation of karyotype elements in the evolution of Calliphorid flies. The observed conservation in polytene banding patterns should facilitate construction of phylogenies over a number of generic groups.     

Ultrastructure and ontogeny of the hair sensilla on the funicle of Calliphora erythrocephala (Insecta,Diptera)

Summary Four envelope cells are responsible for the formation of the basiconical sensilla of Calliphora. They are the thecogen, trichogen, and tormogen cells, and envelope cell 4. In early stages of development the still subepithelial sensory cilia are completely enclosed by the innermost thecogen cell. The first formation movements are initiated by a growth thrust of the hair-forming cell into the exuvial space. The sensory cilia only begin to grow into the hair anlage when the hair-forming cell has almost reached its final length. As soon as growth is completed the trichogen cell, tormogen cell, and envelope cell 4 start to excrete cuticular material. The trichogen cell forms the perforated part of the hair shaft and the stimulus-conducting system consisting of the pore tubules. The tormogen cell is responsible for the excretion of the basal non-perforated hair shaft and sheath cell 4 forms the proximal part of the socket region. The thecogen cell only begin to produce dendritic sheath material when the sensory hair is almost complete.Approximately 7–8 days after pupation the tormogen cell degenerates, having, by this time, produced about two-thirds of the sensilla cuticle. The surrounding envelope cells incorporate cell fragments of the tormogen cell. The trichogen cell continues the secretion where the tormogen cell left off. When the secretion of cuticle is finished the sheath cells begin to withdraw towards the proximal direction and to form microvilli on the apical membrane. The resulting outer receptor lymph space is bordered by envelope cell 4 and the trichogen and thecogen cells. The tormogen cell is absent in the sensilla of the imago.Abbreviations DS dendritic sheath - E4 envelope cell 4 - Ex exuvial space - G glial cell - iD inner dendritic segment - iRL inner receptor lymph space - oRL outer receptor lymph space - oD outer dendritic segment - P pore - PT pore tubules - S sensory cell - T thecogen cell - TO tormogen cell - TR trichogen cell Part 1 of a dissertation accepted by the Faculty of Bio- and Geosciences, University of Karlsruhe     

Different structure of polytene chromosomes ofPhaseolus coccineus suspensors during early embryogenesis

Summary The pattern of DNA and RNA puffs in pair VII of polytene chromosomes has been investigated in the suspensor ofPhaseolus coccineus during early embryo development. The pattern of³H-TdR and³H-U incorporation has been also detected. Collected data indicate that: 1. both heterochromatic regions, p₁₁ and q_(111+112), of chromosome pair VII, organize large DNA puffs; 2. DNA puffs of both regions are specific of different embryo differentiation steps; 3. a seasonal influence on the DNA puffing seems also to be present, as demonstrated by the comparison of the results collected in two different crops; 4. the incorporation experiment by³H-TdR evidences that not all DNA puffs show clustered labeling; 5. the RNA puffing of the two regions seems also to be specific of determined embryo stages.     

Developmental changes in the fine structure of the salivary gland of Trichosia pubescens (Morgante) (Diptera : Sciaridae) in relation to puffing activity

Two differentiated sections (S₁ and S₂) of the salivary gland of Trichosia pubescens (Morgante) (Diptera : Sciaridae) have been examined by electron microscopy for fine structural alterations that occur in the cell cytoplasm during larval development. Such changes have been correlated with the puffing patterns of the polytene chromsomes. During stage 1 (end of the 3rd instar to mid 4th instar), the puffing pattern and the ultrastructure of S₁ and S₂ cells are rather constant. Nevertheless, marked differences are noted when the puffs and the fine structure of the 2 sections are compared. In S₁, secretory material is concentrated and eliminated as membrane-bound granules, while in S₂, secretory granules are not detected and the elimination of secretion seems to occur continuously. At stage 2 (end of the 4th instar), the puffing pattern undergoes considerable alterations simultaneously with the appearance of many ultrastructural modifications. In S₁, the morphological aspect of the secretory granules is altered, while in S₂ a decline in the secretory activity is detected. At stage 3 (older 4th-instar larvae), most of DNA puffs are active, there being no striking differences in the puffing pattern between S₁ and S₂. This stage is marked by the onset of gland histolysis, with the appearance of an intense autophagic activity of lysosomes in S₁ and S₂. As histolysis progresses during stage 4 (prepupae and early pupae) the activity of the polytene chromosomes decreases; most of the cells present a large number of autophagic vacuoles and an increasing disorganization of the cytoplasm, leading to the final lysis of the gland.     

Patterns of puffing activity in the salivary gland chromosomes of Drosophila

The autosomal salivary gland chromosome puffing patterns of Drosophila simulans are described and compared with the puffing patterns of the sibling species D. melanogaster. During the late third larval instar and the prepupal period the patterns of puffing activity of these two species are similar — approximately 50% of the puffs common to both species showing identical activities. The remaining puffs differ in their timing of activity, or in their mean sizes, or in both of these parameters. A number of puffs (14) found in D. simulans have not been regularly observed in the Oregon stock of D. melanogaster but are active in other D. melanogaster strains. One puff (46 A) of D. melanogaster was absent from D. simulans and forms a heterozygous puff in hybrids, when the homologous chromosomes are synapsed. When the homologues are asynapsed a puff at 46 A is restricted to the melanogaster homologue. The puff at 63E on chromosome arm 3L is considerably smaller in D. simulans than in D. melanogaster and this size difference is autonomous in hybrids. Other puffs not common to both species behave non-autonomously in the species hybrid, even when the homologous chromosomes are asynapsed.     

Developmental changes in genome activity in Drosophila lebanonensis casteeli pipkin

Puparium formation in Drosophila lebanonensis casteeli is obviously restricted to a certain phase in circadian oscillation. The question whether or not the release of molting hormone is the actual process which is controlled by the circadian oscillation could be approached by using molting hormone-specific changes in genome activity as indication for changes in hormone titer. The identification of hormone specific changes in the puffing pattern of polytene chromosomes should provide a basis for this study.—To this end, a chromosome map of the 7 polytene chromosome arms (1 acrocentric and 3 metacentric chromosomes) of the species was made. Changes in the puffing pattern associated with puparium formation are described and compared with those occurring in response to experimental administration of -ecdysone.—89 puffs were regularly observed in midthird instar larvae. Prior to puparium formation 5 new puffs arise, one at an early stage and 4 attaining their maximum size immediately before puparium formation. Concomitantly, 5 puffs increase considerably in size. These changes in the puffing pattern can be reproduced by injection of ecdysone.—Upon injection of the hormone a clear differentiation between fast reacting loci (within 30–60 min) and slow reacting loci (after 3–4 hours) can be found. As in other Drosophila species the immediate response (within 30–60 min) comprises more than one (5) locus.In memory of Professor Dr. J. Schultz.     

Influence of the genotype on the polytene chromosome puffing and bioelectrical properties of cellular nuclei of Drosophila melanogaster treated with ecdysone in vivo and in vitro experiments

Activity of polytene chromosome puffs at the 0-hour prepupae stage and bioelectric properties of cellular nuclei of salivary glands were investigated under the influence of the hormone 20-OH-ecdysone in vitro in highly inbred selected lines LA (low activity) and HA (high activity) and their F1 hybrids LA x HA and Ha x LA. The inadaptive line LA differs from the line HA by the smaller size of the puffs. The hybrids exceed the best parental line by the size of the majority of the investigated puffs. In the course of investigation of F1 hybrids Ha x LA chromosomes the phenomenon of heteropuffing has been revealed at the asinapsis sites. In vitro impact of ecdysone increases the electrokinetic potential of cellular nuclei; in hybrids this effect expressed more strongly than in parental lines. The data obtained indicate genetic differences in puffing activity in Drosophila polytene chromosomes as a result of inbreeding, destabilizing selection and heterosis effect, and they also confirm the correlation of bioelectric properties of the nuclear genome with regulation of genetic activity of a cellular nucleus.     

N-banding in polytene chromosomes of Chironomus and Drosophila

The N-banding patterns of the polytene chromosomes of Drosophila melanogaster, Chironomus melanotus, Ch. th. thummi and Ch. th. thummi x Ch. th. piger were studied. In Chironomus the polytene N-banding patterns correspond to the polytene puffing patterns. This is revealed by comparison of the puffing and N-banding patterns of identical chromosomes. Size and staining intensity of the N-bands reflect the size of the puffs as shown by puff induction. There is no evidence that the N-bands are also located in Chironomus heterochromatin or are restricted to the nucleolar organizer regions. In Drosophila the -heterochromatin is strongly N-positive, whereas the -heterochromatin, as well as the Chironomus heterochromatin is not N-banded. Contrary to Chironomus, the puffs in Drosophila polytene chromosomes do not give rise selectively to well stained N-bands. — The N-banding method is interpreted to stain specifically non-histone protein which is (1) accumulated in genetically active chromosome regions and (2) present in a specific type of heterochromatin (-heterochromatin of Drosophila).     

Modeling dark puffs using P-transposons in Drosophila melanogaster polytene chromosomes

Modeling of morphologically unusual "dark" puffs was conducted using Drosophila melanogaster strains transformed by construct P[ry; Prat:bw], in which gene brown is controlled by the promoter of the housekeeping gene Prat. In polytene chromosomes, insertions of this type were shown to form structures that are morphologically similar to small puffs. By contrast, the Broad-Complex (Br-C) locus, which normally produce a dark puff in the 2B region of the X chromosome, forms a typical light-colored puffs when transferred to the 99B region of chromosome 3R using P[hs-BRC-z1]. A comparison of transposon-induced puffs with those appearing during normal development indicates that these puff types are formed via two different mechanisms. One mechanism involves decompaction of weakly transcribed bands and is characteristic of small puffs. The other mechanism is associated with contacts between bands adjacent to the puffing zone, which leads to mixing of inactive condensed and actively transcribed decondensed material and forming of large dark puffs.     

Conservation of nucleolar structure in polytene tissues of Ceratitis capitata (Diptera: Tephritidae)

Nucleolar structure was studied in mitotic and three polytene tissues of the Mediterranean fruit fly, Ceratitis capitata using in situ hybridization with a tritium-labelled rDNA probe and silver staining. In mitotic metaphase chromosomes nucleolar organiser regions were localised in the short arms of both sex chromosomes. In polytene nuclei of trichogen cells, salivary glands and fat body rDNA was detected within nucleoli. Nucleoli in these tissues have a similar structure with rDNA labelling concentrated in a central core. Silver staining resulted in very heavy staining of polytene nucleoli and interphase nucleoli in diploid cells. Silver staining of nucleolar organisers in metaphase chromosomes is weak or absent although the X chromosome has numerous dark silver bands in other locations. The results suggest that nucleolar structure is conserved in polytene tissues contrasting with the variability of autosomal banding patterns and sex chromosome structure. They also indicate that silver staining is not necessarily specific for nucleolar regions.