POLLEN MORPHOLOGY OF HAPLOPAPPUS AND RELATED GENERA (COMPOSITAE—ASTEREAE)

Pollen grains of Haplopappus and related genera in the subtribe Solidaginae from North and South America were examined by light and scanning electron microscopy. The grains are consistently tricolporate and echinate. Some genera can be distinguished by pollen size, spine length, and number of spine rows between colpi. Based on these characters, the divergence of Benitoa from other members of the subtribe, as indicated by its morphology and secondary chemistry, is supported. Additionally, the recently suggested absence of a close relationship between Pyrrocoma and Oonopsis is indicated by their contrasting pollen types. This study demonstrates the potential of pollen studies in distinguishing some taxonomic groups in the Astereae.     

Brachiopod tentacles: Ultrastructure and functional significance of the connective tissue and myoepithelial cells in Terebratalia

Summary The fine structure of the tentacles of the articulate brachiopod Terebratalia transversa has been studied by light and electron microscopy. The epidermis consists of a simple epithelium that is ciliated in frontal and paired latero-frontal or latero-abfrontal longitudinal tracts. Bundles of unsheathed nerve fibers extend longitudinally between the bases of the frontal epidermal cells and appear to end on the connective tissue cylinder; no myoneural junctions were found. The acellular connective tissue cylinder in each tentacle is composed of orthogonal arrays of collagen fibrils embedded in an amorphous matrix. Baffles of parallel crimped collagen fibrils traverse the connective tissue cylinder in regions where it buckles during flexion of the tentacle.The tentacular peritoneum consists of four cell types: 1) common peritoneal cells that line the lateral walls of the coelomic canal, 2) striated and 3) smooth myoepithelial cells that extend along the frontal and abfrontal sides of the coelomic canal, and 4) squamous smooth myoepithelial cells that comprise the tentacular blood channel.Experimental manipulations of a tentacle indicate that its movements are effected by the interaction of the tentacular contractile apparatus and the resilience of the supportive connective tissue cylinder. The frontal contractile bundle is composed of a central group of striated fibers and two lateral groups of smooth fibers which function to flex the tentacle and to hold it down, respectively. The small abfrontal group of smooth myoepithelial cells effects the re-extension of the tentacle, in conjunction with the passive resiliency of the connective tissue cylinder and the concomitant relaxation of the frontal contractile bundle.The authors wish to express their appreciation to Professor Robert L. Fernald for his advice and encouragement throughout the course of this study. Some of the work was conducted at the Friday Harbor Laboratories of the University of Washington. The authors are indebted to the Director, Professor A.O.D. Willows, for use of the facilities. Part of this study was supported by NIH Developmental Biology Training Grant No. 5-T01-HD00266 and NSF grant BMS 7507689     

Genetic studies of the Macushi and Wapishana Indians

Summary Blood samples from 509 Macushi and 623 Wapishana Amerindians of Northern Brazil and Southern Guyana have been analyzed with reference to the occurrence of rare variants and genetic polymorphisms of the following 25 systems: (i) Erythrocyte enzymes: acid phosphatase-1, adenosine deaminase, adenylate kinase-k, carbonic anhydrase-1, carbonic anhydrase-2, esterase A_1,2,3, esterase D, galactose-1-phosphate uridyltransferase, isocitrate dehydrogenase, lactate dehydrogenase, malate dehydrogenase, nucleoside phosphorylase, peptidase A, peptidase B, phosphoglucomutase 1, phosphoglucomutase 2, phosphogluconate dehydrogenase, phosphohexoseisomerase, triosephosphate isomerase and (ii) Serum proteins: albumin, ceruloplasmin, haptoglobin, hemoglobin A, hemoglobin A₂ and transferrin. Fifteen different rare variants were detected, involving 11 of these systems. In addition, a previously undescribed variant of ESA_1,2,3 which achieves polymorphic proportions in both these tribes is described. Excluding this variant, the frequency of rare variants is 1.1/1000 in 12510 determinations in the Macushi and 4.7/1000 in 15 396 determinations in the Wapishana. The ESA_1,2,3, polymorphism was not observed in 382 Makiritare, 232 Yanomama, 146 Piaroa, 404 Cayapo, 190 Kraho and 112 Moro. Irregularities in the intratribal distribution of this polymorphism in the Macushi and Wapishana render a decision as to the tribe of origin impossible at present. Gene frequencies are also given for previosly described polymorphisms of 5 systems: haptoglobin, phosphoglucomutase 1, erythrocyte acid phosphatase, esterase D, and galactose-1-phosphate-uridyl-transferase.Research supported by the National Science Foundation and the Energy Research and Development Administration.     

Laboratory and feral hybridization ofAteles geoffroyi panamensis Kellogg and Goldman 1944 andA. fusciceps robustus Allen 1914 in Panama

A viable, male progeny resulted from a two-year captive pairing of a male red spider monkey (A. g. panamensis) and a female black spider monkey (A. f. robustus). While the pelage colorations of the parental species are distinctive, the offspring was intermediate in appearance during maturation. Such hybridization apparently occurs naturally in Panama; two feral spider monkeys, captured from an area of sympatry in the Province of Panama east of the Canal Zone, were characteristic of the laboratory cross.     

Formation of junctional complexes at sites of contact of hemocytes with tissue elements in degenerating nerves of the crayfish, Orconectes virilis

Hemocytes, which contain large cytoplasmic granules, invade the multilamellate glial sheath of ventral ganglion nerve roots of the crayfish following surgical interruption of these nerves. Electron microscopic examination of sections of plasticembedded tissues and replicas of freeze-cleaved ganglion roots reveals numerous slender cytoplasmic extensions of the hemocytes present in damaged nerve sheaths. Many of these microvillous extensions contact glial cells and filamentous extracellular masses. At sites of contact, the microvilli are flattened and occasionally electron-dense material is present in the hemocyte cytoplasm subjacent to the plasma membrane that is closely apposed to a glial cell or connective tissue. Intramembranous surfaces of hemocyte plasmalemmae exposed by freeze-fracture, exhibit particle aggregates 700–2500 Å in diameter. Individual particles are 95–105 Å in diameter. Since the particle aggregates correspond in overall dimension and position in the cell to the sites of contact of hemocyte processes with other sheath components, it is assumed that the two structures are equivalent and represent a junctional complex very similar in structure to some hemidesmosomes. Results from this study strongly suggest that granulated crustacean hemocytes, in response to surgical injury of nerves, invade the damaged nerve sheath and identify damaged glial cells and connective tissue by forming slender cytoplasmic processes which contact elements of the sheath. Tissue components contacted by the hemocytes may subsequently be phagocytosed by them. This is the first report of an invertebrate hemocyte-mediated response to tissue damage in which evidence is presented that the hemocyte may identify necrotic cells and extracellular matrix by forming junctional complexes with them. Crustacean hemocytes, therefore, are likely much more complex functionally than has been previously estimated.