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Exine Structure of Pantoporate Campanula (Campanulaceae) Species PDF

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Preview Exine Structure of Pantoporate Campanula (Campanulaceae) Species

i STRUCTURE EXINE OF Joan W, Nowickey^ Stanwyn G. Shetler,^ and Nancy PANTOPORATE CAMPANULA Morin^ (CAMPANULACEAE) SPECIES^ Abstract The only species in Campanulaceae known to have pollen with pantoporate apertures are five species of Campanula: C C, americana, C. californica^ C. exigua, C. and sharsmithiae. All other species examined of this large griffinii, 300 The genus (ca. species) have 3-4(-7) pores, spaced equidistant on the equator of the grain. pantoporate species, especially the widely distributed annual or biennial herb C. americana, are further distinguished by elongate or well- may developed columellae. The larger columellae of this species be correlated with their lower density. Except for the similarities in pollen, C. americana does not appear closely related to the three slender annuals, C. exigua, C. and C. sharsmithiae^ each of which has a restricted distribution in California. Campanula americana also griffinii, C not closely related to the pantoporate perennial, californica^ or to the fourth California annual, C. angustiflora, is which has 4-6-zonoporate pollen with a tectum and exine structure almost identical to C. sharsmithiae. The pantoporate grains of C. californica, with pores that are not always uniform in size or distribution, and the zonoporate grains of may C. angustijloray with unevenly distributed pores and elongate columellae, represent transition stages between Campanulaceae the two pollen types. In this study and previous ones, all species of with well-developed or elongate Whether more make columellae have been shown to have a high number (more than five) of apertures. apertures the pollen wall more vulnerable to collapse and whether selective pressures have resulted in a more rigid wall by means of elongate columellae are debatable. The highly distinctive pollen-collecting hairs found in the Campanuloideae are and illustrated discussed. In a systematic study of four closely related Although not specifically studied here, the pol- annual species of Campanula, endemic to Cal- lination biology of Campanula, the species of which all ifornia, Morin (1980) established the existence of show pronounced protandry and adaptations to in- pantoporate characterized by a unique and (pores distributed over the entire sur- sects, is still largely unexplained mechanism. While the flower griffi is still and Morin, and C. sharsmithiae Morin, and 4-6-zono- in bud, anthers dehisce deposit the pollen on the pollen-collecting hairs of the upper As style. ifl Morin (unpublished) found the pantoporate aper- anthesis proceeds, both pollen and the unicellular hairs gradually disappear, the former owing rermial C. calif to pol- (Kell. Heller), Prior to her studies only one other linator activity, the latter to retraction/invagina- expanded The annual or tion into their bases. fact that in some Campanula cases the retracted hair observed "to trap" biennial americana native to east- is L,, has prompted ern and central North America, was known to have a pollen grain speculation that the an autogamy a pantoporate aperture type (Avetisian, 1967; invagination is adaptation for (for Dunbar, review, see Shetler, 1979). This does not seem 1973a, 1975a, 1981, 1984; Shetler, to b, b, & 1982; americana be the case (Shetler, 1982; Lloyd Yates, 1982), for life history of C. see Shetler, & 1958, and The unusual however; the possible functions of the collecting Baskin Baskin, 1984). hairs are presented in the discussion section. lim in Campanulaceae prompted investigation of this exme Methods and Materials the California pantoporate species. For examination of pollen, anthers were re- sub] mov herbarium fundamental tolyzed (Erdtman, 1966) for preparations: rod all light microscopy (LM), scanning electron microscopy like or threadlike structures TEM We preparation and John Skvaria for the preparation of pollen ' thank Carol Annable for her assistance in Campanula sharsmithiae. wr t • • Washim_-gton, i-. Museum Smithsonian Institution. D.C. 20560, Natural History. ' Department Botany National of of L.S.A. 631660299, U.S.A. Box 299, Louis, Mifisouri ' Missouri Garden, P.O. St. Botanical Card. 65-80. Ann. Missouri Bot. 79: 1992. 66 Annals of the Garden Missouri Botanical and tectum copy (SEM), transmission electron microscopy porate apertures a that consists of and (TEM), and plasma spinules irregularly oriented threadlike or -ashing. rod- SEM, 1-41, For pollen was coated with carbon, then like structures (Figs. 54, 55, 57, 58). For Dunbar and examined and photographed porate Campanulaceae, (1984: gold-palladium, 1) classi- 250 with a Cambridge Stereoscan Electron Micro- fied surface sculpture types into the following cat- scope or a Hitachi 570 SEM, egories: ridges; ridges, with top end bent upwards; TEM, For pollen was incoi:porated into agar, fingerlike structures; protrusions; irregular ridges; ^ fixed with osmium tetroxide, stained with uranyl and reticulum in low relief. With the exception of Campanula acetate, and embedded in Spurrs resin or L. R. the last category, applicable only to we White. After sectioning, the pollen was stained in americana in our study, believe that these lead citrate and examined in a JEOL 100, 1200EX, closely related categories are minor variations in 200 Although or a Philips transmission electron microscope. the orientation of the rods or threads. LM, For pollen was mounted in glycerin jeDy the term rod, with implication of a straight or its may and sealed with paraffin. Measurements (see Table erect linear structure, be more fitting for some are based on 20 grains LM. tecta than others, Figure 41 versus Figures 1) in e.g., For examination of collecting hairs, styles were 55 or 58, we will use rod in the remainder of the ( dissected from herbarium flowers and attached to text to describe the ropelike strands making up the specimen stubs, coated with gold-palladium, and surface of the tectum, often intertwined in spaghet- examined and photographed in a Cambridge 250 tilike fashion. These rods can vary in their size, S410 or an scanning electron microscope. The degree of distinction (e.g.. Figs, 15, 31 vs. 9, 41), examined 35 and collections are listed in Table 1. extent of projection (e.g., Fig. vs. 38, 41), In plasma-ashing an electrical changes orientation mostly horizontal as in Fig- 35 or field di- (e.g., atomic oxygen into excited oxygen ions to form a with rods more erect /vertical as in Figs. 17, 23, highly reactive plasma that causes low temperature and 46). combustion of organic molecules. The most com- In SEM, the relationship between the rods and — mon appear use of plasma-ashing is for removal of organic spinules seems clear the free tips of rods Campanula matter from inorganic structures, e.g., tissue from to coalesce to form spinules. In every sponge For SEM, some spicules. this application, end-point de- species examined in the base of at least tectors can determine precisely when the organic spinules continuous with three or more rods. This is layers have been removed. In completely plasma-ashed organic condition the illustrated best in is samples such as exines, however, the only control samples. Figures 56 and 59, but ahnost as well in (available to us) is duration of ashing. Based on an Figures 8, 29, 38, 41, and 58. In the past (Dunbar, earlier study of pollen from 33 species representing 1973a; Morin, have been con- 1980), the spinules & we now owic but sidered as basally rooted or divided, ir oduces the most profound a think that the spinules are the result of free tips taring of rods coalescing and not of rods formed by the in skeletonlike exines. For greater detail, see No- basal subdivision of spinules (see discussion below). wicke et al. (1986). In thin section, species examined have strat- all LM EM and All slides micrographs are deposited ified exines with an endexine, foot layer, columel- at the Palynological Laboratory, National Museum lae, and tectum, but these components are van- of Natural History, Smithsonian Institution, ously developed. poUen oi Based on the above the characteristics a Campanula with porate a recognizable type: is tectum and oriented consisting of spinules variously Results n two rods. But the pores defines distribution of the n In the course of the entire Campanulaceae study, distinctive subtypes with very unequal frequencies, the pollen of 5 8 collections representing 41 species Five species are pantoporate 7, 13, 21, (Figs. 1, mined SEM, many and 24), with as few as apertures and as six examined som^- »?enty- as 8. All remaining campanulas have three, 1 LM examined a times more (seven in in four, or rarely five or six TEM. examined few grains of C. rotundifolia) pores placed equ>- For most the part only the species that are cited distant on the equator of the grain (some grains of the and/or in text Ulustrated are given Table in 1. C. anguslijlora excepted). Campanula TEM All 18 species of cited Table Our in differ- 1 investigation revealed subtle have oblate-spheroidal or spheroidal pollen with ences panto- in the structure of the exine: the in Si Table examined, voucher and numbers. S}jccic6 data, pollen data, figure 1. Number Pore of CD Species Collection Location Figure(s) Grain pores size^ size CO & Campanula alpina Jacq. Bujorean Nyarady 7/1/23 Romania 28-30 P(28) 30 X E(30) 32 4-5.2 3 s.n, (32) (35) C amerirana L. Danaske 2128 Wisconsin (36) 38 (40) 5.2-6.5 12-15 3 Shimek 8/15/27 3-6 10-13 38 5.2-6.5 s.n. low, (35) (40) CD & Soper Dale 4081 Canada 1.2 38 5.2-6.5 10-13 (35) (39) 1472 62-69 Hartley Wisconsin 60. WardsM. 4/7/1878 Maryland 61 C. angustijlora Eastwood Constance aL 3045 16-20 P(29)31 X E(31)34(36) 4-6.5 et California (32) (4-)6 C barbata L. Hermann 19483 France 33-35 P(29) 32 X E(30) 31 5.2-6.5 3 (34) (34) C biiumgartcnii Becker Hall 3125 Germany 57-59 P(27)29(31) X E(30)31(43) 3-4 5.2 J. MrMurphy 22 24-27 C. californiia (Kill.) H**ller California 40 2.6-4 7-11 (39) (45) 2116 C. fiivarirnta Mic hx. Allard Virginia P(30) 32 X E(32) 35 5.2-6.5 3 (35) (36) Duncan 11925 South Carolina P(29)31 (34) X E(32)34(36) 5.2 3 C & exigrta Rattan Sharsmith Sharsmith 3358 40 12-14 California 7,8, (36) (42) 5.2 10-12 Morin 297 (MO) California 9 35 4-5.2 12-15 (34) (38) glome r. rata L. CoUins Fernahl 1904 Canada P(29)30(34) X E(31)33(38) <?- s.n, 4.5-6.5 (2)3(4) m Morin 20 (MO) C. g^iffinii Griffin 4 1 California 13, 14 (30)31(34) 5.2-6.5 6-9 X O Hon 21813 ell California 15 33 4-5.2 7-12 (30) (35) O C CD hagutin Rrrhinger 3678 Roisft. Greece 31,32 P(21) 23 X E(22) 25 3.9-5.2 (25) (26) 3(4) C/) C CD la^inrarpn Cham. 7/15/61 llultvn $M. Alask P(30) 32 X E(31) 33 5.2-6.5 3-4 (35) (35) C CD DC & Cay FTiarrorAira ex A. fTiUzck Dutoit 21-Vn-30 France P(27) 29 (30) X E(29) 31 4-5.2 (33) 3 (2) (4) C 0) mrrfium Thomas 10926 L. Montana 54-56 P(34) 37 X E(36) 39 (39) 3 (40) C CD rhomboidaiis 37599 L. Maillrfrr 36-38 Switzerland P(26) 29 X E(28) 29 4-5.2 O (31) (34) 3(4) C rolundifolia L. Charpin 7/15/69 et at. $.n. Italy 39 P(32) 37 X E(34) 36 5.2-6.5 3-4 (40) (41) 3858 Colorado 40.41 P(30) 33 X 36 (38) E(34) (41) 5.2-6.5 4(5) C, iharsmiihiae Morin Morin 301 (MO) 21-23 I California (35) 38 (40) 4-5.2 12-18 C 2977 sibirira L. r^ato Romania P(29)32(34) X E(31)33(36) 5.6-7.1 (2)3(4) 5U1 Codonopsi'f bulleyana Rock 51-53 China P(41) 44 X E(41) 46 17-36 6-8 (48) (49) 0) Forrrst ex Diels C rnrtvolvulacea Kurs Rock 6603 42-44 China P(38)42(48) X E(43)46(51) 7.8-13 6 Githopsis pair h Vatke CoHilance 5/19/51 ilia 45-47 s.n. Califo rnia P(36) 40 X E(39) 43 5.8-7.8 (45) (47) 6 DC tf'ahlcnbergia Unarioidrs Schtmr: 10R77 48-50 Argentina P(25) 28 X E(29) 31 4.5-5.2 (30) (32) 3(4) inieat a iks: numbe lar diniension; C7> ' 68 Annals of the Garden Missouri Botanical The remaining pantoporate prominent pollen of the species, porate type the or project through the tectum to form the core of life 21 sharsmithiae igures 10, 11, 19, 20, 12), C. (Figs. 5, ^"Z- LM 13-1 was examined and SEM. 27, whereas in the zonoporate type the columeDae finii (Figs. 5), in The were examined TEM, are reduced Figs. 30, 32, and 37) and the first three species also in (e.g., C 4* annual, angustifi columella Campanula The nnial califc has a well-developed foot layer (Figs. 32, 34, (Figs. 24-27) has the elongate columellae asso- *' ally with the DantoDorate type, but the distri 37). i. A complete description of each pollen type bution and size of the pores are not unifo is LM numerous given below; for pollen size, the range of the mean there are grains that, in optical have pores on the "equator'; (Table given. section, four to six 1) is » may each hemisphere and bottom focus) have (top — emi, PANTOPORATE POLLEN TYPE FIGURES 21-27 1-15, hemisphe ^ Pollen spheroidal, 31-40 /im diam., with 6-18 a pore; very frequently one of the pores is distinctly even LM, 4-6.5 The obvious in pores, the pores /im diam., the tectum con- smaller. elongate spinules, from sisting of rods and spinules, or microreticulate and would distinguish the pollen of C. californica remaining spinulate; exine structure consisting of lamellate all endexine prominently thickened at the pores; the tions suggest that the pollen of C. califc but foot layer mostly thin or sometimes eaual betwe in thick- int zonoporate. ness to the nonapertural endexine; the columellae closer to the pantoporate than to the elongate, prominent, at least some of which project Campanula exigua 7- 12-15 pan- (Figs. 1 2) is through the tectum to form the core of most sometimes spi- tectum nules; the incomplete or nearly complete rods 4 jmericana, and endexine are simila sities of the foot layer iffif them C. C. and making characterize life ta, C. (Fig. 11), difficult to g^iffi it sharsmithiae. form well-defined individually, but together they a Campanula americana 1-6) 12-15- becomes much near the pores, (Figs. unit that thicker is pantoporate with a microreticulate tectum in which The columellae, although not as large as in C. m mebu- rods americana, predominant layer are the Campanula species of examined in this study or poral (nonapertural) areas, and most appear to form the illustrated in others (Dunbar, 1973a, b, 1975a, project through the irregular tectum to 1984; Morin, 1980) has a microreticulate tectum core of the spinules. Their elongation is under- or such massive columellae. The rods/rauri and scored in tangential section (Fig. 11) by the pro- spinules are more evident in some grains than in portion of the area they occupy. In botn total others. In thin section (Figs. 3-5), the exine of C. rods dis americana some and consists of a lamellate endexine present tinct from each other and are short, throughout the grain but greatly thickened near appear vertical. the pores and with a thin foot layer. Comparison grifiniiy Griffi C of radial sections of americana (Fig. 3) with oDorate with a 1 C those of other pantoporate species, exigua e,g., tectum (Fig. 11), C. sharsmithiae (Fig. 22), and C. cal was 8-11 more poorly de- 15), -pantoporate with fined rod tectal {f< 12' alpina and e.g., C. (Fig. 30) C. hagiela Campanula 21-23) (Fig. 32), sharsmithiae is (Figs. emphasizes the unusual development of the colu- with mellae in C. americana. Larger columellae may as rods, sist of irregularly defined elements as well be a compensation or species for, correlation with, fewer In exme thin section 22) the of this (Fig. The columellae density of columellae that in the tan- consists of a thick, mostly lamellate endexine gential section of C. americana much foot (Fig. 4) is is slightly less electron dense than the thin lower than that exigua when which in C. (Fig. 10): a layer and weU-developed some of columellae, Ihe grid proiect through the tectum form spinules. to columellae e structures nvunber of columellae ami for C, similar. C while that for C. exigua was 30. c^ In contrast Campanula americana^ to - Number Volume Nowicke 69 79, et 1 al. Campanula 1992 Exine Structure of — — SEM SEM Figures 1-6. SEM and TEM of Campanula americana pollen. 1. of two pantoporate grains. 2. — TEM Note massive columellae, some of which project through of tectum. 3. of radial section including part of pore. TEM the tectum, and endexine nearer the pore,— 4. of tangential section. Perforated tectum thickened, lamellate TEM 6.-5. (outer SEM, Figures 2 and of mostly radial section through whole ring) agrees with that portrayed in gram. otherwise indicated. tectum ;im unless 1 form spinules; exine structure consists of a lamel- ifornica^ C. exigua, C, griffi much becomes endexine that thicker near the knowledge late a well-developed foot layer that thicker pores; pollen that 3-4(-7)-zonoporate. is is than the nonapertural endexine; reduced or short and a complete or almost complete — columellae; zonoporate pollen type smaD with to large spinules that are not tectimi, Figures 16-20. 28-41. 58 54. 55. 57, continuous with columellae. C The pollen of seven zonoporate species, diameter al- Pollen mostly oblate-spheroidal, Polar 28-30), pina C. angustiflora (25-)31- Jacq. (Figs. (Figs. (23-)29-37Mm x diameter Equatorial C C barbata 33-35), baum- 16-20), L. (Figs. C. 39 3-4 the fim, pores (rarely 7, rotundifolia), hamela Becker 57, ^artenii (Figs. 58), C. Boiss. (= J. pores circular or elongated polarly lo- , slightly rhomh,oida, li, s C. L. (Figs. 36-38), 4.0-6.5 Mm, the (Figs. 31, 32), longateX dimension the longest difoli With quently with a free some of which coalesce to tip, Annals the 70 of Garden Missouri Botanical — --o- Figures 7-15. SEM 8. grain. igua. of pantoporate 7. TEM Note tectum tectum section. 10. ooff tangential — TEM ol and tectal perforations the large area occupied by columellae cut at right angle to their long axes. 11- — radial section. Note prominent columellae, some of which project through tectum, 12. TEM of section of whole — C SEM fewer grain. Note buildup of endexine near apertures. 13-15. 13. of wwhnooliee ggrraaimn.. Note llaarrggeeir atxnnd^ *--^ griffinii. I'NOie — SEM " ^S'E"*M' a«nnnotthheer apertures than in the remaining pantoporate species. 14. of tectum.— 1^ 5. of*• tectum ^from = coUection (see Table 1). Scale bars 1 /xm unless otherwise indicated. Number Volume Nowicke 79, 1 et 71 al. 1992 Exine Structure of Campanula C SEM SEM TEM Campanula poUen. 16-20. anguslijl. 16. of zonoporate grainn. Figures 16-23. and of TEM -17. SEM tectum.- 18. o! section of whole Th of grain. Note and irregularity of pore distribution size. clo« bemg indicates that the section is to paraHel with the that the four apertures are similar in size visible > they are well above or below the equator.- TEM on the right side 19. equator apertures of the grain. If there are TEM -20. through tectum. Note some columellac project tin: of tangential that including part of pore. 2\-2^ and \0 C.nharsmitkiae.-2]. SEM Figures 4 section. Compare columeUae and area occupied with of size endexme and lamellate md.-ates TEM The thickened proximity an -22. to section. pantoporate of radial grains. - Figure angustijlora. 17. Scale Lars unlw, aperture.-23. SEM Compare with tectum of C. 1 ^n. of tectum. otherwise indicated. - 72 Annals of the Garden Missouri Botanical SEM TEM Figures 24-32. and Campanula SEM 24-27. grain- of pantoporate pollen. C. californica.—24:. of — SEM Note long TEM spines. 25. of tectum diameter with part of pore. 26. of tangential section. Compare the — jmmcuae TEM with those in Figure 10 of C. exigua and in Figure 37 of C. rotundifolia. 27 of slighdy . C dial sections of two grains. Note elongate columellae and the direct connection with spinules. 28-30. SEM alpina. 28. —of zonoporate grain in equatorial view.— 29. SEM of tectum with pore. Note direct relationship TEM of spines with rods. 30. of oblique sections of two grains. 31, 32. C. hagiela.— SI. SEM of tectum. Note small irregular-sized spinules and lack of distinction of rods.— 32. TEM of grain including radial section of collapsed two Note = walls. well-developed foot layer, small columellae, and almost continuous unless tectum. Scale bars 1 iiia otherwise indicated. of C. angustiflora, discussed separately below, the Campanula 36-38) has rhomboidalis (Figs, exines of the above species are grain similar: irregularly pollen with three pores on the equator of the oriented rods that are distinct, e.g.. Figure 41 or and a tectum of the (Fig. 38) that representative , is TEM barely Figure and visible, e.g., 31, poorly devel- genus. In most prominent unit (Fig. 37) the oped or short columellae with the foot lay er/endex- columellae the is foot layer /endexine, while the ine the predominant component (Figs. 30, 32, 34, are very short 37, 40). Of TEM, the zooporate examined species in 73 Nowicke Number et Volume 79, al. 1 Campanula Exine Structure of 1992 I I SEM 33-35. barbata. 33. of zonoporate gi C. TEM Campanula poUen. SEM Figures and of SEM C of polar view of 3 porate rhomboidalis.- 36. 36-38. TEM ^^ SF.M tectum. .^^ of 39 - tectum. 41. C. rotumlifc 1 6"™^ TEH secHon. »' •"" „^ grain.- obBqua radial '°^^ 37. o( slightly ^„ion. TTo met ^romto=,.t „f component is ri sJk 74 Annals of the Garden Missouri Botanical I Campanula harhata (Fig. 34) has the most well- lower grain In Figure 47 to Codonopsis convol- U vulaceae defined, albeit short, columellae. (Fig. 44). Campanula The Wahlenhergia Although pollen of linarioides the pollen of angustiflora (Figs. 16-20) zonoporate, the higher number of 48-50) 3-zonoporate with a typically campan- (Figs. is is pores —(4-6) and their somewhat irregular distri- ulaceous tectum and exine structure. bution necessarily equidistant from each oth- As part of an earlier study (Nowicke et al., 1986) ^not — two er and not on the equator distinguishes this of substructure of distinct pollen types (a corn- all many pound [= and pollen from zonoporate types. Moreover, the layer of striae lirae] a derived tri- 3 tectum and exine structure link this armual to the angular array) that occurred together in a number C Some pantoporate ones. grains of angustiflora of families, exines of Berberidaceae, Cistaceae, Eu- (Fig, 17) have a tectum that almost indistin- phorbiaceae, and Geraniaceae were partially de- is C guishable from some grains of sharsmithiae graded by plasma-ashing (see Materials and Meth- — To (Fig. 23) both have irregularly shaped elements ods). better judge the effect of plasma-ashing in addition to rods. Most likely these elements are on these two pollen types, additional exines, b- derivatives of the horizontal rods; perhaps they are eluding species of Campanulaceae, were ashed and only the free tips. Clearly, the exine structure examined in SEM. Control (nonashed) and ashed is more similar to that of the pantoporate species exines of Codonopsis hulleyana (Figs. 51-53), than to the zonoporate species: elongate columellae Campanula medium (Figs. 54-56), and C. baum- in C. angustiflora (Fig. 19) project through the garteni (Figs. 57-59) are illustrated in high-mag- Campanula tectum to form spinules like the pantoporate taxa nification SEMs. In the two species plasma-ashing shows the rod- (Fig. 22), (Figs. 56, 59) clearly s For purposes of comparison, species of three like substructure of the spinules as well as the other genera of Campanulaceae are tectum. In Codonopsis hulleyana^ however, there illustrated here: no Codonopsis convolvulacea Kurs (Figs. 42-44), are no spinules, and in the control there is Githopsis pulchella Vatke (Figs. 45-47), and evidence of rods (Figs. 51, 52), xinlike in a second 39- Wahlenhergia DC. linarioides (Figs. 48-50). species, Codonopsis convolvulaceae (Figs. Codonopsis convolvulacea 42-44) After plasma-ashing 60 minutes, a network (Figs. 41). for is campan- 7-zonocolpate with short colpi and a tectum with (Fig. 53), not unlike the rods in typical TEM densely spaced rods and large spinules. In ulaceous tecta, evident. The small protuberances is (Fig. 44), however, distinct from most Cam- could be interpreted as vestiges of the free tip oi it is many panulaceae: a well-defined endexine, no foot layer, rods. Thus the tectum of C. hulleyana (Fig- and columellae that appear to terminate abruptly, 52) may represent a reduced stage in which the with an outer irregular layer seemingly composed has for identity of the rods (as well as spinules) may of very short columellae connected to the rods. intents and purposes, been or rep- all lost, it Some inner columellae narrow at the interface and resent a primitive which these elements state in then become expanded again in the outer layer of have not yet become differentiated, TEM None columellae. of the grains examined in had and a foot-layer, the columellae extended as Discussion such to the endexine. Codonopsis hulleyana For- rest ex Diels, Figures 51 and 52, also examined For the most part our agree with those results TEM in but not illustrated here, has a very gen- of Dunbar (1984), who characterized the pollen of eralized exine structure with a definite foot layer Campanula as having bacula that "are generally and where simple columellae (Nowicke, unpublished and data), short stubble-like except one species in Githopsis pulchella 45-47) (Figs. 6-7(-8)- they are high." The which she referred is exception to zonoporate, as in other species of the genus (Morin, ana. Dunbar, although aware ol tnc 1983), with a tectum remarkably Cam- had similar to he pantoporate California species, ^ panula angustiflora and them (Fig. 1 7) C, sharsmithiae pportunity examine (apparently) to (Fig. 23) in which the rods appear more The erect. thin section, fact that the radial section in Figure 47 somewhat The Campanula ameri- between is relationship has enhanced oblique the thickness of the foot cana and the four pantoporate California species layer/endexine and obscured the continuity of most perplexing. Although *'microperforate" tec- is the C columellae as spinules. Other sections (Nowicke, turn of americana from the distinguishes it show unpublished) most, not very columellae two if all, pro- California species, all five species share through jecting the tectum. Note also the resem- restricted, Campanula, poUen charac- at least in blance of the inner surface of the tectum ters— col- in the pantoporate aperture type and elongate

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