The structure, formation, histochemistry, fate, and functions of the spermatophore of Lytta nuttalli Say (Coleoptera: Meloidae)

1971 ◽  
Vol 49 (12) ◽  
pp. 1595-1610 ◽  
Author(s):  
G. H. Gerber ◽  
N. S. Church ◽  
J. G. Rempel
Keyword(s):  
Tube Wall ◽  
Anterior Part ◽  
Posterior Part ◽  
Accessory Gland ◽  
Male Accessory Gland ◽  
Male And Female ◽  
Male Accessory Glands ◽  
Accessory Glands ◽  
Sequence Of Events ◽  
Probable Form

The spermatophore of Lytta nuttalli consists of a unique tubular structure and a mass of jelly-like material (JLM). The spermatozoa are located in the JLM at its junction with the tube. The tube wall is composed of three layers of "histochemically" different substances produced by the first pair of male accessory glands. The JLM is secreted by the vasa deferentia. During copulation, usually of 8 to 10 h duration, the tube is molded and hardened in the vagina and posterior part of the spermatophoral receptacle duct and the JLM in the anterior part of the duct. The tube of the spermatophore serves as an intromittent "organ" in the absence of an internal penial sac. The sequence of events in spermatophore formation and the roles of the materials from the second and third pairs of male accessory glands are described. After copulation, usually within 2 h, the tube is ejected by the female. Within 24 h after copulation, most of the spermatozoa are transferred to the spermatheca. The secretion of the female accessory gland apparently is involved in this process. The JLM and third male accessory gland materials are retained in the spermatophoral receptacle and apparently are absorbed. The histochemical composition of the male and female secretions and the components of the spermatophore and the cytology and secretory cycles of the glands are described. The spermatophore of L. nuttalli is compared with those of other insects and the probable form of the spermatophore in other Meloidae is considered.

FUNCTIONS OF THE MALE ACCESSORY GLAND SECRETIONS OF AEDES MOSQUITOES (DIPTERA: CULICIDAE): TRANSPLANTATION STUDIES

1976 ◽  
Vol 108 (9) ◽  
pp. 955-960 ◽  
Author(s):  
S. Ramalingam ◽  
G. B. Craig
Keyword(s):  
Aedes Aegypti ◽  
Secretory Granules ◽  
Accessory Gland ◽  
Anterior Region ◽  
Male Accessory Gland ◽  
Male Accessory Glands ◽  
Accessory Glands ◽  
Aedes Mosquitoes ◽  
Species Specific

AbstractIn Aedes aegypti, the ’matrone’ substance which caused mating inhibition and stimulated oviposition in females, was present in the anterior secretory region of the male accessory glands. In the divided accessory glands of male A. triseriatus, however, it was present in the posterior glands. The posterior gland substance in A. triseriatus was not species specific. It stimulated oviposition in A. aegypti and caused mating inhibition in A. atropalpus. The secretory substance of the posteriormost region in the glands of both species of mosquitoes was mucin in nature. This mucin substance effectively glued the secretory granules of the anterior region(s).

Memoirs: The Morphology and Development of the Genitalia and Genital Ducts of Homoptera and Zygoptera as Shown in the Life Histories of Philaenus and Agrion

1928 ◽  
Vol s2-72 (287) ◽  
pp. 447-483
Author(s):  
C. J. GEORGE
Keyword(s):  
Anterior Part ◽  
Ejaculatory Duct ◽  
Accessory Gland ◽  
Posterior Region ◽  
Anterior Region ◽  
Vaginal Opening ◽  
Forward Region ◽  
Efferent System ◽  
Accessory Glands ◽  
The Common

1. In the male Philaenus and Agrion the vasa deferentia terminate on the ninth segment in the early stages. An ectodermal invagination from that segment joins them subsequently and thus the male gonopore is established. 2. The accessory glands develop in Philaenus male from the anterior end of the swollen extremities of the vasa deferentia and the vesiculae seminales from a still more forward region. 3. The accessory glands of the male are mesodermal in origin and not ectodermal as some authors state. 4. There is no evidence as to the existence of a ‘pair of ectodermal ejaculatory’ ducts either in Philaenus orin Agrion, and reasons are adduced to show that they do not exist at all in the higher Insecta. 5. In the female nymph of Philaenus the oviducts terminate on the seventh segment. They are subsequently joined by an ectodermal invagination from the seventh segment. The common oviduct is formed in two parts: the anterior part is derived from the posterior region of the invagination on the seventh and the posterior region is formed as a groove from the ectodermis of the eighth segment and subsequently this groove is converted into a tube. When the second part is completed it is in connexion with the invagination from the seventh and opens to the outside on the eighth segment. The ectodermal invagination from the seventh also gives rise to the spermatheca. A median accessory gland develops as an invagination from the ninth segment between the bases of the inner ovipositor lobes. A pair of accessory glands develop as paired imaginations from the anterior region of the ninth segment. 6. In the female nymph of Agrion the oviducts fuse to form a single duct and terminate in the middle of the eighth segment. Posteriorly an ectodermal invagination from the eighth segment meets this duct and lies in a position dorsal to it. Later on the ectodermal invagination develops a spermatheca dorsally and the mesodermal and the ectodermal ducts unite into one. The accessory glands develop as paired ectodermal invaginations from the anterior region of the ninth segment. 7. The female gonopore is not homologous in the different groups of insects. The vaginal opening in Orthoptera, Hymenoptera, Homoptera, Diptera, and Lepidoptera is homologous. The vaginal opening in Coleoptera is homologous with the oviducal opening of Lepidoptera, with the opening of the accessory gland of Homoptera, Hymenoptera, Diptera, Isoptera, and the opening of the spermatheca in some Orthoptera. 8. The common oviduct, being formed differently in the different groups is not homologous. The accessory organs, e. g. spermatheca, are not homologous in the different groups. 9. There is no evidence to show that the common oviduct is of paired origin. 10. The occurrence of a median accessory structure on the ninth segment which develops in the young as an invagination between the bases of the inner ovipositor lobes is very general in the higher Insecta. In some it functions as a gland, in others as a storehouse for spermatozoa. 11. The homology of the paired accessory glands is indicated. 12. The male genital ducts are not strictly homologous with those of the female. The homologue of the ejaculatory duct is the invagination from the ninth segment in the female. 13. The Odonata stand isolated in having a mesodermal region for the common oviduct and in the peculiar development of the two processes between the anterior ovipositor lobes. 14. The probable lines of evolution of the female efferent system in Insecta are indicated. The study of the development of the female efferent system indicates that the groups Orthoptera, Homoptera, Lepidoptera, and Diptera are very closely allied. Coleoptera seem to have had quite a different line of evolution from the above groups in this respect. 15. The adult Odonatan anatomy of the genital organs in the female as observed by me is in some respects different from that described by Tillyard. In conclusion I wish to express my deep sense of gratitude towards Professor Balfour-Browne and Dr. J. W. Munroe, both of whom have always been ready to help me. My colleague Mr. R. I. Nel, who is working on similar lines in this department,, has rendered me valuable help, not only in matters connected with the subject proper but also in translating difficult German references. I am also indebted to Mr. Peter Gray who helped me a good deal in translating references in Italian.

Ejaculation and spermatophore formation in Culicoides melleus (Coq.) (Diptera: Ceratopogonidae)

1981 ◽  
Vol 59 (3) ◽  
pp. 332-346 ◽  
Author(s):  
J. R. Linley
Keyword(s):  
Electron Micrographs ◽  
Male Genitalia ◽  
Accessory Gland ◽  
Seminal Vesicles ◽  
Sperm Transfer ◽  
Male Accessory Gland ◽  
Male And Female ◽  
Membrane Complex

This paper describes the initial stages of sperm transfer in Culicoides melleus. A description of the male and female reproductive tracts is given and an account of events during the first 2 min of coitus. In this period the male secretes a spermatophore, which, during copulation, is held predominantly in the male genitalia. The course of ejaculation, involving passage of spermatozoa through the seminal vesicles and glutinous glands of the male accessory gland, and subsequently through the ejaculatory ducts, is described. Extrusion of the spermatophore at the aedeagus is illustrated and an explanation advanced to account for encapsulation of the sperm masses. The structure and content of the spermatophore is described with the aid of electron micrographs. A feature of particular interest is the "membrane complex," secreted prior to ejaculation by cells of the glutinous glands. The complex consists of a layer of membranes, which separates the ejaculate from the spermatophore walls.

The structure and possible function of the signum ofGlossina tabaniformisWestwood

Parasitology ◽  
1963 ◽  
Vol 53 (1-2) ◽  
pp. 145-153 ◽  
Author(s):  
A. M. Jordan
Keyword(s):  
Anterior Part ◽  
West African ◽  
Tsetse Flies ◽  
The West ◽  
Male Accessory Glands ◽  
Flame Photometer ◽  
Accessory Glands ◽  
Protective Shield

1. In all species of thefuscagroup of tsetse flies (Glossina), exceptG. brevipalpisNewstead, a gelatinous structure, the genital fossa, is present at the anterior end of the uterus. On the surface of the genital fossa is a toughened structure known as the signum.2. Probably chitin and certainly calcium are present in the substance of the signum ofG. tabaniformisWestwood. An opaque concretion develops on the signum after the female has been fertilized. The concretions may be caused by a reaction between sperms or secretions from the male accessory glands and materials in the substance of the genital fossa; the possibility that the concretions are ‘mating scars’ produced by pressure of the harpes of the male on the signum is considered unlikely. Concretions are not present on the signa of all species.3. A possible mechanism of fertilization inG. tabaniformisis discussed, and it is suggested that the signum may act as a protective shield for the anterior part of the uterus and common oviduct of the female from the harpes of the male which are inserted into the uterus during coitus. The views of Machado (1959) are discussed and it is agreed that the signum probably acts as a protective shield in all species in which it occurs and differences in the form of the signum between species may be related to differences in the form of the harpes of the male.I wish to thank Dr J. Williamson for chromatography, Dr L. E. Stephen and Mr K. E. Broomfield for advice and assistance with the sectioning of the signa, Dr F. Peers for operating the Flame Photometer, Dr D. G. Godfrey for suggesting that the signa should be examined for calcium, and Mr W. Petana for taking the photomicrographs.I am indebted to Dr K. C. Willett, Director of the West African Institute for Trypanosomiasis Research, for criticism of the manuscript.

THE REPRODUCTIVE ORGANS OF THE VELVET MITE, ALLOTHROMBIUM LEROUXI (TROMBIDIFORMES: TROMBIDIIDAE)

1970 ◽  
Vol 102 (2) ◽  
pp. 144-157 ◽  
Author(s):  
S. N. Mathur ◽  
E. J. LeRoux
Keyword(s):  
Seminal Vesicle ◽  
Ejaculatory Duct ◽  
Reproductive Organs ◽  
Accessory Gland ◽  
Male And Female ◽  
Accessory Glands ◽  
Receptaculum Seminis ◽  
Female Reproductive Organs

AbstractThe anatomy and functions of the male and female reproductive organs of Allothrombium lerouxi Moss are described in detail. In the male, the reproductive organs consist of paired testes, paired vasa diferentia, a median seminal vesicle, a median ejaculatory duct, bursa expulsatoria, a penis, and a median accessory gland; in the female, they consist of paired ovaries, paired oviducts, a median uterus and a vagina. The function of the parts in the male differs from that reported in other species of Trombidiformes, and in females fertilization takes place in the spongy epithelium of the uterus instead of in the oviducts as in oribatids. Females also lack a receptaculum seminis and accessory glands.

Male accessory gland substance: an egg-laying stimulant in Melanoplus sanguinipes (F.) (Orthoptera:Acrididae)

1969 ◽  
Vol 47 (6) ◽  
pp. 1199-1203 ◽  
Author(s):  
R. Pickford ◽  
Al B. Ewen ◽  
C. Gillott
Keyword(s):  
Seminal Vesicle ◽  
Chemical Substance ◽  
Accessory Gland ◽  
Egg Laying ◽  
Melanoplus Sanguinipes ◽  
Male Accessory Gland ◽  
Accessory Glands ◽  
Egg Deposition ◽  
Complete Set ◽  
Per Se

The rate of egg deposition by mature virgin females of the migratory grasshopper, Melanoplus sanguinipes (F.), increased markedly after implantation of accessory glands from mature males. Implants consisting of one-half of a complete set of glands, or of the 10 short hyaline glands alone, were about equally effective in increasing the rate of egg deposition. However, in each case the oviposition rate was less than that of normally mated females of the same age. Implanting only the white glands of the accessory gland complex had a lesser effect on egg-laying and implants of the long hyaline gland or of the seminal vesicle had little or no effect.Our results indicate that the physical act of mating per se or the presence of sperm probably do not provide the primary stimulus to egg-laying. The abdominal location of the implanted accessory gland does, however, suggest that some diffusible chemical substance is responsible for increasing egg deposition in these virgin females.

EFFECTS OF TESTOSTERONE, TESTOSTERONE METABOLITES AND ANTI-ANDROGENS ON THE FUNCTION OF THE MALE ACCESSORY GLANDS IN THE RABBIT AND RAT

1977 ◽  
Vol 74 (1) ◽  
pp. 75-88 ◽  
Author(s):  
ROY JONES
Keyword(s):  
Adverse Effects ◽  
Differential Effect ◽  
Cyproterone Acetate ◽  
Testosterone Propionate ◽  
Secretory Activity ◽  
Accessory Gland ◽  
Male Accessory Glands ◽  
Accessory Glands ◽  
Gland Function ◽  
Testosterone Metabolites

The androgenic potencies of testosterone, 5α-dihydrotestosterone, 5α-androstane-3α,17β-diol and 5α-androstane-3β,17β-diol towards the prostate, glandula seminalis + glandula vesicularis, ampullae and epididymis were evaluated after administration to castrated rabbits. The influence of cyproterone acetate, stilboestrol and medrogestone on accessory gland function was also investigated in rabbits and rats. In the rabbit it was found that the minimum dose of testosterone propionate that would maintain the function of all accessory glands at normal levels was approximately 200 μg/ animal/day. Higher levels of testosterone propionate overstimulated the function of the prostate, glandula seminalis + glandula vesicularis and ampullae, but did not affect the epididymis. Whereas testosterone propionate and 5α-dihydrotestosterone propionate were essentially equipotent in their capacity to support growth and secretory activity and stimulated all the accessory glands, 5α-androstane-3α,17β-diol dipropionate had a pronounced differential effect; it was considerably more potent than testosterone propionate in promoting secretion in the prostate, but was ineffective in maintaining the function of the epididymis. 5α-Androstane-3β,17β-diol dipropionate was the weakest androgen tested. Evidence also indicated that the potency of a steroid can depend on whether it is administered as its free or esterified form. Cyproterone acetate suppressed fructose secretion in the prostate of the rabbit but had no adverse effects on the function of the epididymis in either the rabbit or rat. Stilboestrol was the most potent anti-androgen tested and medrogestone the least effective.

MALE ACCESSORY GLAND FACTORS ELICIT CHANGE FROM ‘VIRGIN’ TO ‘MATED’ BEHAVIOUR IN THE FEMALE CORN EARWORM MOTH HELICOVERPA ZEA

1993 ◽  
Vol 183 (1) ◽  
pp. 61-76 ◽  
Author(s):  
T. G. Kingan ◽  
P. A. Thomas-Laemont ◽  
A. K. Raina
Keyword(s):  
Sex Pheromone ◽  
Helicoverpa Zea ◽  
High Performance ◽  
Accessory Gland ◽  
Corn Earworm ◽  
Male Accessory Gland ◽  
Reverse Phase ◽  
Accessory Glands ◽  
Calling Behaviour ◽  
Chemical Messenger

After mating, the females of many species of moths become depleted of sex pheromone, calling behaviour is terminated, and they become transiently or permanently unreceptive to additional matings. In the corn earworm moth, Helicoverpa zea, we have found that the male accessory gland/duplex is required for evoking the post-mating depletion of sex pheromone but apparently not for the cessation of calling. The latter change requires the receipt of a spermatophore or a chemical messenger derived from non-accessory gland/duplex sources. Desalted extracts of combined accessory glands and duplexes caused a depletion of pheromone in injected females. Proteinaceous components in extracts purified by fractionation in cation-exchange cartridges and by reverse-phase high-performance liquid chromotography retain their pheromonostatic activity. In addition, this fractionated material shuts off calling behaviour and prevents mating in injected females, raising the possibility that redundant mechanisms exist in eliciting the different components of ‘mated’ behaviour.

scholarly journals Specificity and localization of lipolytic activity in adult Drosophila melanogaster

1994 ◽  
Vol 304 (3) ◽  
pp. 775-779 ◽  
Author(s):  
G M Smith ◽  
K Rothwell ◽  
S L Wood ◽  
S J Yeaman ◽  
M Bownes
Keyword(s):  
Drosophila Melanogaster ◽  
Lipase Activity ◽  
Specific Activity ◽  
Lipolytic Activity ◽  
Accessory Gland ◽  
Null Mutant ◽  
Male Accessory Gland ◽  
Accessory Glands ◽  
Esterase 6 ◽  
Adult Drosophila

The triacylglycerol lipases present in adult Drosophila melanogaster have been investigated. Different lipase activities are present in various tissues in the fly. In particular, an abundant lipase activity is present in the male accessory gland. An esterase null mutant was used to confirm that the enzyme activity was due to a distinct lipase and not non-specific activity from esterase 6 which is also abundant in accessory glands. The properties of the accessory-gland lipase were investigated, and pH optima and substrate utilization suggest that it has some similarities to vertebrate bile-salt-stimulated lipase. Lipase activity is significantly reduced in males and increased in females shortly after mating. This finding suggests that lipase activity is transferred to the female and may be important in mating and reproduction in Drosophila.

Male accessory secretions, their use and replenishment in Glossina (Diptera, Glossinidae)

1974 ◽  
Vol 64 (4) ◽  
pp. 533-539 ◽  
Author(s):  
J. N. Pollock
Keyword(s):  
Accessory Gland ◽  
Field Conditions ◽  
Mating Frequency ◽  
Distilled Water ◽  
Body Measurements ◽  
Male Accessory Glands ◽  
Glossina Austeni ◽  
Accessory Glands ◽  
Virgin Male ◽  
Saline Medium

AbstractThe male accessory glands of Glossina austeni Newst. contain an apical secretion—a dense, opaque, whitish secretion at the apical end of the gland, and a diffuse secretion—a bulkier, more mobile, translucent, whitish secretion occupying nearly all the remainder of the gland. There is also a plug of clear solidified accessory material preventing the outflow of secretions from the resting gland. By immersing the whole accessory gland in a saline medium at pH 2·2, and then transferring the specimen to distilled water, the apical secretion can be separated manually from the rest of the gland, as an apical body. Measurements of the apical body in virgin male flies show that the apical body increases in width according to the equation: Age ≐ constant Χ width 2.5, but individual deviations from this relation were considerable. Immediately after mating the apical body is long and thin; recovery to approximately the resting condition is complete after 48 h, but, on average, mated males have thinner apical bodies than virgin males of the same age. The use of apical secretion measurements to assess mating frequency under field conditions might be possible if adequate samples of males were available.

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