American Journal of Botany 90(12): 1788–1800. 2003.
CHROMOSOME STUDIES OF CHEILANTHOID FERNS
(PTERIDACEAE: CHEILANTHOIDEAE) FROM THE
WESTERN UNITED STATES AND MEXICO1
MICHAEL D. WINDHAM2,4
2
AND
GEORGE YATSKIEVYCH3
University of Utah, Utah Museum of Natural History, 1390 E. President’s Circle, Salt Lake City, Utah 84112 USA; and
3
Missouri Botanical Garden, P.O. Box 299, St. Louis, Missouri 63166 USA
Although analyses of chromosome numbers represent a fundamental step in the study of any group of organisms, the xeric-adapted
cheilanthoid ferns (Pteridaceae: subfamily Cheilanthoideae) have received little attention from cytogeneticists due to the difficulty in
obtaining samples and accurate chromosome counts. In an effort to clarify patterns of chromosomal evolution in this group, we present
131 chromosome counts representing 75 taxa of cheilanthoid ferns from the western United States and Mexico. First reports are
provided for 24 taxa, including the first count for the genus Cheiloplecton. Nine other taxa yielded numbers that had not been reported
previously. Our data suggest that chromosome base numbers are more stable than previously thought and that much of the reported
variation may involve erroneous counts. When coupled with published DNA sequence data, our counts suggest that the plesiomorphic
base number of subfamily Cheilanthoideae is x 5 30 and that x 5 29 has arisen just once or twice among the taxa studied.
Key words: Argyrochosma; Cheilanthes; Cheilanthoideae; Cheiloplecton; chromosomes; cytotaxonomy; Mexico; Notholaena;
Pteridaceae; western United States.
To plant biologists interested in patterns of genetic variation
and evolution, analyses of chromosome numbers represent a
fundamental step in the study of any group of organisms.
Chromosome counts provide indispensible information on genetic discontinuities within and among species, and they contribute to our understanding of phylogenetic relationships at
all taxonomic levels (e.g., Semple et al., 1989; Pinkava et al.,
1992; Baldwin et al., 2002). Realizing the value of chromosome data for evolutionary studies, systematists have pursued
the long-term goal of determining chromosome numbers for
as many species and populations as possible (Carr et al., 1999;
Strother and Panero, 2001). Ubiquitous or economically important families such as Asteraceae and Poaceae have benefited greatly from this attention, but many other groups remain
undersampled.
Among the undersampled taxa, the xeric-adapted cheilanthoid ferns (Pteridaceae subfamily Cheilanthoideae) present a
special challenge to cytogeneticists. As is typical of homosporous ferns (see Haufler and Soltis, 1986), the chromosome
numbers of cheilanthoids are high, with the lowest record being x 5 27. Many species are confined to remote desert habitats, where they tend to grow from rock cracks or specialized
substrates that make transplantation difficult. Finally, meiotic
studies in the group have been limited by the fact that sporangia are scattered (not aggregated into discrete sori) and usually
are protected by a covering of hairs, scales, and/or reflexed
marginal indusia. All these factors have contributed to the perception that cheilanthoid ferns are chromosomally intractable,
Manuscript received 8 April 2003; revision accepted 24 July 2003.
The authors thank Dr. Christopher Haufler for encouraging this study and
providing necessary facilities and equipment; Tom Ranker, Dale Benham,
Alan Smith, Ralph Brooks, and Jim Morefield for supplying some of the
samples; curators at ASU, KANU, and UNLV for permission to remove
spores from their collections; Jill Schwartz, Dave Finley, and Dawn Farkas
for help assembling the figures. Financial assistance from the University of
Kansas, Utah Museum of Natural History, and Mr. Donavon Lyngholm is
gratefully acknowledged.
4
E-mail: windham@umnh.utah.edu
1
with the result that fewer than 20% of the species have been
counted to date.
The limited number and questionable accuracy of counts
available for many cheilanthoid ferns have hindered attempts
to determine generic base numbers and resolve phylogenetic
relationships (Reeves, 1979). The problems are especially
acute in Cheilanthes, the largest and most diverse genus of
subfamily Cheilanthoideae. Published reports for Cheilanthes
suggest that closely related species (or populations of a single
species) often have different base numbers. Although infraspecific chromosomal variability is common in angiosperms,
it is rarely encountered among the ferns and fern allies, in
which the chromosome base numbers of most genera are extraordinarily stable (Britton, 1974). In genera with a variable
base number, such as Lycopodium (Wilce, 1972) and Thelypteris (Smith, 1971), each subgenus or section usually has a
stable number. Examples of seemingly random variation in
chromosome base number are rare, and most of these seem to
occur in groups (such as the cheilanthoid ferns) in which little
cytogenetic work has been done. The systematic value of chromosome data for these taxa is limited because it is unclear
whether reported variations in base number represent real biological phenomena or erroneous counts. The situation can be
resolved only by more intensive sampling of the taxa in question. The current study was undertaken for this purpose.
The goals of this study are twofold: (1) to expand the taxonomic and geographic sample of chromosome counts available to researchers interested in the systematics of cheilanthoid
ferns and (2) to use this information in conjunction with published reports to assess the stability of generic and infrageneric
base numbers in the group. This report focuses on taxa found
in the western United States and Mexico, the region in which
cheilanthoid ferns achieve their greatest diversity (Tryon and
Tryon, 1973). Species from other regions will be addressed in
future papers.
MATERIALS AND METHODS
The majority of chromosome counts presented in this study were obtained
from meiotic material gathered from field-collected or greenhouse-grown
1788
December 2003]
WINDHAM
AND
YATSKIEVYCH—CHROMOSOME
plants. Expanding fertile leaves were killed in Farmer’s fixative (3 parts absolute ethanol : 1 part glacial acetic acid) and stored at 2208C. Just prior to
use, fixed material was transferred to 70% ethanol to soften the leaf tissue
and facilitate the removal of sporangia. Individual sporangia at the proper
stage of development (with a whitish center and transparent periphery) were
transfered to a drop of 1% acetocarmine using the tip of a fine dissecting
needle. When 25–50 sporangia had been accumulated, the stain was mixed
with Hoyer’s medium (1 : 1) and squashed following traditional methods
(Manton, 1950). Meiotic chromosome counts were derived from sporocytes
at late diplotene or diakinesis. A few mitotic chromosome counts were obtained by germinating spores from herbarium specimens following procedures
outlined by Windham et al. (1986). The resultant gametophytes were prepared
using the protocol of Windham and Haufler (1986). Meiotic and mitotic cells
providing interpretable counts were photographed using a Zeiss (Zeiss, Oberkochen, Germany) phase contrast microscope and Kodak Technical Pan
2415 film (Kodak, Rochester, New York, USA). Photographs are provided for
those taxa for which our determinations differ from previously published
counts.
To guide the discussion, we compiled a list of previously published chromosome counts for all taxa studied. This list was assembled by checking all
accepted names and commonly used synonyms through the Cytotaxonomical
Atlas of the Pteridophyta (Löve et al., 1977) and a complete set of the Index
to Plant Chromosome Numbers spanning the period 1975–1997 (Goldblatt,
1981, 1984, 1985, 1988; Goldblatt and Johnson, 1990, 1991, 1994, 1996,
1998, 2000). The primary literature was consulted to obtain voucher information and check photographic documentation for each count identified by
this search.
A significant number of cheilanthoid ferns reproduce apogamously (Gastony and Windham, 1989), and an overview of the apogamous life cycle is
necessary to understand some of the methods and results of this study. In the
standard Döpp-Manton type of apogamy, sporocytes experience an endomitotic event just prior to meiosis that doubles the number of chromosomes in
the cells. Thus, for example, chromosomally unbalanced triploids momentarily
behave as hexaploids. Through pairing of duplicate chromosomes, meiosis
proceeds normally. The resultant spores are genetically identical to the triploid
sporophytes from which they were derived (Gastony and Windham, 1989),
and they germinate to produce triploid gametophytes. Because the sporophytes
and gametophytes exist at the same ploidy level (i.e., n 5 2n), completion of
the apogamous life cycle does not involve fertilization. Instead, the rapidly
developing gametophyte produces a sporophyte by simple budding, usually
without the formation of sexual organs (gametangia).
Due to the frequency of apogamy among cheilanthoid ferns and its bearing
on perceived ploidy levels, gametophyte cultures were established (following
Windham et al., 1986) for all taxa whose life cycle had not been ascertained
by previous studies. Free water necessary for fertilization was withheld from
these cultures to determine whether the gametophytes were capable of producing sporophytes apogamously. If sporophytes developed under these conditions (especially in the absence of gametangia), the taxon was considered
apogamous. However, if gametangia developed normally and sporophyte production did not occur without fertilization, the taxon was classified as sexually
reproducing.
RESULTS AND DISCUSSION
A total of 131 chromosome counts was obtained for 75 taxa
of cheilanthoid ferns from the western United States and Mexico; these are listed alphabetically by genus and species group
in Table 1. First reports are provided for 24 taxa, including
the first chromosome count for the genus Cheiloplecton. Nine
other taxa yielded numbers that had not been reported previously. The significance of these counts and the insights they
provide regarding the stability and evolution of base numbers
will be discussed.
Argyrochosma—Although Argyrochosma often has been
included in the genus Notholaena, Windham (1987) separated
STUDIES OF CHEILANTHOID FERNS
1789
the two groups because of consistent differences in rhizome
scales, leaf architecture, sporangial distribution, spore and gametophyte morphology, chemical composition of the farinose
indument, and chromosome number. Subsequent chromosome
work on this group yielded first reports for four taxa (Table
1). Both the widespread A. incana and the Mexican endemic
A. pallens were sexual diploids with n 5 27. Argyrochosma
formosa and A. limitanea subsp. mexicana proved to be apogamous triploids with n 5 2n 5 81. An earlier tetraploid count
for A. jonesii (as Notholaena jonesii in MacNeill et al., 1978)
was corroborated by another collection from California, but
two samples from Arizona revealed that the species also encompasses a sexual diploid cytotype exhibiting n 5 27. Published reports of n 5 27 for A. delicatula (Windham, 1987)
and A. fendleri (as Notholaena fendleri in Brooks, 1986) are
based on our work and are repeated here because the original
citations lacked voucher information. The three remaining taxa
of Argyrochosma appearing in Table 1 are subject to conflicting reports that require additional discussion.
Wagner (1963) published a count of n 5 27 for A. dealbata
(as Notholaena dealbata). This report was misquoted as 2n 5
58 by Löve et al. (1977), contributing to the mistaken assumption (e.g., Tryon and Tryon, 1982) that the base number
of Argyrochosma was x 5 29. Additional collections from
three populations spanning much of the range of A. dealbata
confirm that the chromosome number of the species is, indeed,
n 5 27 (Fig. 1).
Argyrochosma limitanea subsp. limitanea has been the subject of two earlier reports (as Notholaena limitanea). Schaack
et al. (1982) listed a count of 2n 5 c. 84 from Colossal Cave,
Arizona, while Benham and Schaack (1988) reported n 5 81
from essentially the same population. Samples from four additional localities in southeastern Arizona demonstrate that this
taxon is an apogamous triploid with n 5 2n 5 81 (Fig. 2).
Knobloch et al. (1973) reported chromosome counts of n 5
29 and 2n 5 c. 116 for A. microphylla (as Notholaena parvifolia). This is the only report in the primary literature that
supports assertions by Tryon and Tryon (1982) that the base
number of Argyrochosma is x 5 29. However, the photograph
documenting this report is just as easily interpreted as n 5 27,
leaving the true chromosome number of this species in question. Material gathered during this study near the northern and
southern limits of the species range clearly show that the diploid chromosome number of A. microphylla is n 5 27 (Fig.
3).
Nine of the 16 species attributed to Argyrochosma by Windham (1987) have now been studied cytogenetically. All taxa
showed chromosome counts based on x 5 27, a number
unique among cheilanthoid ferns. Recent molecular work by
Gastony and Rollo (1998) strongly supports the monophyly of
this group and indicates that Argyrochosma is more closely
related to Pellaea (with x 5 29) than it is to Notholaena (with
x 5 30).
Aspidotis—Although Aspidotis is sometimes included in
Cheilanthes (e.g., Tryon and Tryon, 1982), most recent authors
follow Lellinger (1968) in treating this small group as a distinct genus. Our study mirrors previous counts by Smith
(1975) for A. californica, A. carlotta-halliae, and A. densa.
All but one recognized taxon (the African species A. schimperi) have now been studied chromosomally, and they consistently have a base number of x 5 30.
Genus
Taxon
ARGYROCHOSMA
A. dealbata (Pursh) Windham
Chromosome
count
Mode of
reproduction
S
S
*A. formosa (Liebm.) Windham
n 5 2n 5 81
A
*A. incana (Presl) Windham
n 5 27
S
**A. jonesii (Maxon) Windham
n 5 27
S
A. jonesii (Maxon) Windham
n 5 54
S
A. limitanea (Maxon) Windham subsp. limitanea
n 5 2n 5 81a
A
*A. limitanea (Maxon) Windham subsp. mexicana (Maxon) Windham
**A. microphylla (Mett. ex Kuhn) Windham
n 5 2n 5 81
A
n 5 27
S
*A. pallens (Weath.) Windham
n 5 27
S
ASPIDOTIS
A. californica (Hook.) Nutt. ex Copel.
n 5 30
S
A. californica (Hook.) Nutt. ex Copel.
n 5 60
S
A. carlotta-halliae (Wagner & Gilbert) Lellinger
n 5 60
S
A. densa (Brack.) Lellinger
n 5 30
S
n 5 2n 5 116
A
n 5 29
S
n 5 2n 5 87
A
n 5 2n 5 87
A
ASTROLEPIS
A. cochisensis (Goodd.) Benham & Windham
subsp. arizonica Benham
A. cochisensis (Goodd.) Benham & Windham
subsp. chihuahuensis Benham
A. cochisensis (Goodd.) Benham & Windham
subsp. cochisensis
A. integerrima (Hook.) Benham & Windham
a
UNITED STATES. California: Monterey Co., Nacimiento-Furgusson Rd. between Jolon &
Hwy. 101, R 893 (UT); San Diego Co., along San Diegito River WSW of Lake Hodges,
W 856 (UT).
UNITED STATES. California: Monterey Co., Nacimiento-Furgusson Rd. between Jolon &
Hwy. 101, R 887 (UT).
UNITED STATES. California: Marin Co., vicinity of Bootjack Picnic Area along Panorama
Hwy., R & Smith 902 (NY, UC, UT), R & Smith 904a (BRY, UC, UT).
UNITED STATES. California: El Dorado Co., ENE of Kyburz below Cup Lake near head
of Tamarack Creek, W 2581 (MO, UT). Washington: Chelan Co., above Ingalls Creek on
SE slopes of the Stuart Range, W & Alverson 823 (NY, UT).
UNITED STATES. Arizona: Yavapai Co., along small tributary on E side of Black Canyon,
W & Morefield 443 (UT).
MEXICO. Coahuila: SE of Saltillo, Benham 1348 (ASC).
UNITED STATES. Arizona: Cochise Co., SW slopes of the Dragoon Mts., WY 378 (MO,
UT); Yavapai Co., along small tributary of Dry Creek, W & Czech 600 (UC, UT).
UNITED STATES. Arizona: Cochise Co., Huachuca Mts., Garden Canyon, Y 84-11 (IND,
UT); SW slopes of the Dragoon Mts., WY 377 (UT); New Mexico: Grant Co., along unnamed tributary of the Mimbres River, WY 766 (UT).
[Vol. 90
n 5 27
n 5 27
BOTANY
A. delicatula (Maxon & Weath.) Windham
A. fendleri (Kunze) Windham
UNITED STATES. Kansas: Montgomery Co., below overlook park at Elk City Reservoir
dam, Brooks 16997 (KANU, UT); Oklahoma: Murray Co., Turner Falls State Park, WY
727 (UT); Texas: Blanco Co., Pedernales Falls, WY 738 (UT).
MEXICO. Nuevo León: WSW of Linares on Mex. Route 60, WYR 482 (KANU, NY, UT).
UNITED STATES. Colorado: Clear Creek Co., 1.6 km NE of I-70 on US 6, Y & McCrary
84-152 (UT); New Mexico: Torrance Co., Manzano Mts., Cañon del Trigo, W 352 (ASC,
KANU, MO).
MEXICO. Oaxaca: c. 8 km NW of Huajuapan de León along Mex. Route 190, WYR 523
(UT); NE of Putla de Guerrero along Mex. Route 125, WYR 539 (UT); along Mex. Route
131 c. 3 km due S of San Miguel Sola de Vega, WYR 551 (KANU, UT).
UNITED STATES. Arizona: Santa Cruz Co., Pajarito Mts., Alamo Canyon, WY 224 (ASC,
ASU, UT), WY 228 (ASC); Santa Cruz Co., Santa Rita Mts., Ash Canyon, WY 332 (ASC,
BRY, MO, UC, UT); New Mexico: Hidalgo Co., Peloncillo Mts., Guadalupe Canyon, WY
374 (ASC, UT).
UNITED STATES. Arizona: Mohave Co., along I-15 on S side of Virgin River, W & Ramsey 91-026 (UT); Pima Co., NE slope of the Waterman Mts., WY 249 (ASC, UT).
UNITED STATES. California: Inyo Co., White Mts., near Antelope Springs, Morefield
1664a (UT).
UNITED STATES. Arizona: Cochise Co., Huachuca Mts., Copper Canyon, W 459 (NY,
UT), Scheelite Canyon, W 171 (UT); Mule Mts., Box Canyon, Y 84-194 (ARIZ, UT);
SW slopes of the Dragoon Mts., WY 428 (UT).
MEXICO. Coahuila: c. 40 km SE of Saltillo along Mex. Route 57, WYR 575 (MO, NY,
UC, UT).
MEXICO. Coahuila: c. 40 km SE of Saltillo along Mex. Route 57, WYR 576 (UT).
UNITED STATES. Texas: along US 385 on NE side of the Glass Mts., WY 740 (UT).
MEXICO. Oaxaca: c. 26 km SE of Huajuapan de León along Mex. Route 190, WYR 527
(MO, NY, UT).
OF
S
Collection locality and voucher
AMERICAN JOURNAL
n 5 27a
1790
TABLE 1. Chromosome counts for cheilanthoid ferns. Symbols: * indicates first report for taxon; ** indicates previously unreported chromosome number for taxon. Mode of reproduction:
S 5 sexual; A 5 apogamous. Abbreviations for primary collectors: W 5 M. D. Windham; Y 5 G. A. Yatskievych; R 5 T. A. Ranker. Herbaria housing voucher specimens are
identified by uppercase abbreviations (based on Holmgren et al., 1990) following the collection numbers.
Continued.
Genus
Taxon
A. sinuata (Lag. ex Sw.) Benham & Windham
subsp. mexicana Benham
A. windhamii Benham
Mode of
reproduction
n 5 29
S
n 5 2n 5 87
A
n 5 30
n 5 30
S
S
Collection locality and voucher
UNITED STATES. Texas: Jeff Davis Co., Davis Mts., Little Aguja Canyon, Benham 968
(ASC).
UNITED STATES. Arizona: Yavapai Co., along small tributary of Dry Creek, W & Czech
599 (UT).
S
MEXICO. Oaxaca: N of San Pedro Juchitengo along Mex. Route 131, WYR 544 (UT).
n 5 2n 5 90
A
**C. feei Moore
n 5 2n 5 90a
A
C. leucopoda Link
*C. longipila Baker
C. newberryi (D. Eaton) Domin
n 5 30
n 5 30
n 5 30
S
S
S
UNITED STATES. Arizona: Cochise Co., Huachuca Mts., Huachuca Canyon, W & Haufler
634 (UT).
UNITED STATES. Arizona: Cochise Co., Huachuca Mts., Copper Canyon, W 460 (MO,
UT); Coconino Co., SE side of Elden Mtn., W 87 (ASC, UT).
MEXICO. Tamaulipas: SW of Cd. Victoria along Mex. Route 101, WYR 493 (UT).
MEXICO. Nuevo León: WSW of Linares along Mex. Route 60, WYR 475 (UT).
UNITED STATES. California: Orange Co., along tributary of Hot Spring Canyon in the
Santa Ana Mts., W 98-093 (UT); San Diego Co., SW of Escondido along small tributary
of San Diegito River, W 98-086 (COLO, MO, NY, UT).
n 5 2n 5 90a
A
n 5 2n 5 90
A
n 5 29a
S
n 5 29
n 5 29
n 5 58
S
S
S
n 5 30
S
C. eatonii Baker
n 5 2n 5 90a
A
C. fendleri Hook.
n 5 30
S
**C. lendigera (Cav.) Swartz
*C. lindheimeri Hook.
C. tomentosa Link
n 5 60a
n 5 2n 5 90
n 5 2n 5 90a
S
A
A
CHEILANTHES (‘‘marginata group’’)
**C. arizonica (Maxon) Mickel
*C. cuneata Link
CHEILANTHES (‘‘microphylla group’’)
C. aemula Maxon
C. alabamensis (Buckl.) Kunze
*C. horridula Maxon
*C. horridula Maxon
CHEILANTHES (‘‘myriophylla group’’)
C. covillei Maxon
UNITED STATES. Arizona: Cochise Co., Chiricahua Mts., Rucker Canyon, YW 82-221
(ARIZ); Huachuca Mts., Huachuca Canyon, W 301 (ASC, MO, UT); Ramsey Canyon, W
99 (ASC, UT).
MEXICO. Oaxaca: along tributary of Rio Socorro in the Sierra Juarez E of Íxtlan de Juarez, WYR 566 (UT).
MEXICO. Nuevo León: along state Hwy. 16 in the Sierra El Fraile, WYR 465 (UT); WSW
of Linares along Mex. Route 60, WYR 474 (UT).
MEXICO. Nuevo León: WSW of Linares along Mex. Route 60, WYR 477b (NY, UT).
MEXICO. Nuevo León: along State Hwy. 16 in the Sierra El Fraile, WYR 470 (UT).
UNITED STATES. Texas: Burnet Co., along Route P4 in Longhorn Cavern State Park, WY
732 (UT).
1791
UNITED STATES. California: Riverside Co., San Jacinto Mts., along tributary of Dry
Creek, W 713 (UT).
MEXICO. Coahuila: c. 40 km SE of Saltillo along Mex. Route 57, WYR 578 (UT).
UNITED STATES. Arizona: Cochise Co., Huachuca Mts., Copper Canyon, W 237 (ASC,
MO, UC, UT); Garden Canyon, Y 84-09 (IND, UT).
UNITED STATES. Arizona: Coconino Co., SE side of Little LO Spring Canyon, W 185
(ASC, UT), W of US Route 89A in Oak Creek Canyon, W & DeTar 92-265 (UT); Gila
Co., Mazatzal Mts., Barnhardt Canyon, W & Morefield 448 (UC, UT).
UNITED STATES. Arizona: Cochise Co., Huachuca Mts., Huachuca Canyon, W 304 (UT).
UNITED STATES. Arizona: Cochise Co., SW slopes of the Dragoon Mts., WY 426 (UT).
MEXICO. Nuevo León: WSW of Linares along Mex. Route 60, WYR 473 (UT).
UNITED STATES. Arizona: Cochise Co., Huachuca Mts., Copper Canyon, W 234 (ASC,
UC, UT); Graham Co., Pinaleno Mts., Wet Canyon, W & Haufler 620 (UT).
STUDIES OF CHEILANTHOID FERNS
n 5 30
CHEILANTHES (‘‘fraseri group’’)
C. bonariensis (Willd.) Proctor
B. pedata (Swartz) Fourn.
YATSKIEVYCH—CHROMOSOME
A
CHEILANTHES (‘‘brandegei group’’)
*C. aurea Baker
AND
n 5 2n 5 90
MEXICO. Oaxaca: Hwy 131, 1.7 km N of bridge at Juchitengo, RWY 732 (KANU, UC).
UNITED STATES. Arizona: Cochise Co., Huachuca Mts., Huachuca Canyon, W 299 (ASC,
UT); Santa Cruz Co., Atascosa Mts., along Ruby-Nogales Rd., W 55 (ASC, UT).
MEXICO. Morelos: N of Mex. Route 138 c. 3 km E of Tejalpa, WYR 516 (UT).
WINDHAM
BOMMERIA
B. elegans (Dav.) Ranker & Haufler
B. hispida (Mett.) Underw.
Chromosome
count
December 2003]
TABLE 1.
1792
TABLE 1.
Continued.
Genus
Taxon
Chromosome
count
Mode of
reproduction
**C. villosa Davenp. ex Maxon
n 5 2n 5 90a
A
C. wootonii Maxon
C. yavapensis Reeves ex Windham
n 5 2n 5 90
n 5 2n 5 120a
A
A
n 5 30
n 5 30
S
S
*C. lozanii (Maxon) Tryon & Tryon var. seemannii (Hook.) Mickel & Beitel
*C. pringlei Davenp.
n 5 30
S
n 5 30
S
C. subcordata (D. Eaton ex Davenp.) Mickel
**C. wrightii Hook.
n 5 30
n 5 30a
S
S
n 5 2n 5 90
A
MEXICO. Puebla: c. 11 km NW of turnoff to Zapotitlan, Oax., along Mex. Route 190,
WYR 522 (UT).
n 5 30
S
JAMAICA. St. Andrew Parish: about 3.2 km S of Gordon Town on rd. to Guava Ridge, R
& Trapp 849 (KANU, UC).
n 5 2n 5 90
A
MEXICO. Oaxaca: Along Mex. Route 131 N of San Pedro Juchitengo, WYR 550 (COLO,
UT).
n 5 2n 5 90
A
*N. bryopoda Maxon
n 5 30
S
*N. californica D. Eaton subsp. californica
n 5 2n 5 150
A
*N. candida (Mart. & Gal.) Hook.
n 5 30
S
N. copelandii C.C. Hall
n 5 30
S
N. galeottii Fée
*N. grayi Davenp. subsp. grayi
N. greggii (Mett. ex Kuhn) Maxon
n 5 2n 5 90
n 5 2n 5 90
n 5 30
A
A
S
*N. lemmonii D. Eaton
n 5 30
S
*N. neglecta Maxon
*N. neglecta Maxon
n 5 30
n 5 2n 5 90
S
A
MEXICO. Nuevo León: WSW of Linares along Mex. Route 60, WYR 480 (UT); San Luis
Potosı́: along Mex. Route 57 c. 77 km NE of Cd. San Luis Potosı́, WYR 574 (UT); Tamaulipas: SW of Cd. Victoria along Mex. Route 101, WYR 496 (UT).
UNITED STATES. Arizona: Cochise Co., SW slope of the Dragoon Mts., W 242 (UT), W
244 (ASC, ASU).
MEXICO. Nuevo León: just N of Mex. Route 60 along rd. to Galeana, WYR 485 (MO, NY,
UC, UT).
UNITED STATES. Arizona: Yavapai Co., small E wall tributary of Black Canyon, W 222
(ASC, NY, UC, UT).
MEXICO. Morelos: N of Mex. Route 138 c. 3 km E of Tejalpa, WYR 515 (UT); Oaxaca:
N of San Pedro Juchitengo along Mex. Route 131, WYR 543 (MO, UC, UT); Puebla: SE
of Izucar de Matamoros along Mex. Route 190, WYR 521 (UT).
MEXICO. Nuevo León: along State Hwy. 16 in the Sierra El Fraile, WYR 468 (NY, UT);
WSW of Linares along Mex. Route 60, WYR 472 (UC, UT); Tamaulipas: SW of Cd.
Victoria along Mex. Route 101, WYR 497 (UT).
MEXICO. Oaxaca: NE of Putla de Guerrero along Mex. Route 125, WYR 540 (UT).
UNITED STATES. Arizona: Cochise Co., SW slopes of the Dragoon Mts., WY 427 (UT).
UNITED STATES. Texas: Brewster Co., Big Bend National Park, Y & McCrary 85–10
(IND, UT).
UNITED STATES. Arizona: Santa Cruz Co., Pajarito Mts., Alamo Canyon, WY 229 (ASC,
UT).
MEXICO. Nuevo León: along State Hwy. 16 in the Sierra El Fraile, WYR 467 (UT).
UNITED STATES. Arizona: Cochise Co., SW slope of the Dragoon Mts., W 243 (ASC,
NY, UC), W 245 (ASC, UT).
CHEILANTHES (‘‘incertae sedis’’)
*C. brachypus (Kunze) Kunze
C. gryphus Mickel
HEMIONITIS
H. palmata L.
BOTANY
NOTHOLAENA
*N. aschenborniana Klotzsch
OF
MILDELLA
*M. intramarginalis (Kaulf. ex Link) Trev. var.
serratifolia (Hook. & Baker) Hall & Lellinger
MEXICO. Morelos: N of Mex. Route 138 c. 3 km E of Tejalpa, WYR 517 (UT).
MEXICO. Nayarit: Hwy. 200, between Colonias and El Refilon S of Tepic, RY 799
(KANU).
MEXICO. Sonora: 3.5 km N of El Taymuco, Lehto 24797 (ASU); 1.2 km N of El Taymuco, Lehto 24807A (ASU).
UNITED STATES. Arizona: Pima Co., Tucson Mts., in canyon just E of Gates Pass, WY
248 (ASC, ASU).
MEXICO. Oaxaca: Hwy. 125, 5.3 km N of Ixcapa town center, RWY 729 (KANU, UC).
UNITED STATES. Arizona: Pima Co., Santa Rita Mts., Madera Canyon, W 165 (ASC,
UT); Santa Cruz Co., Pajarito Mts., Alamo Canyon, W 456 (UT).
AMERICAN JOURNAL
*CHEILOPLECTON
*C. rigidum (Swartz) Fée var. lanceolatum C.C.
Hall ex Mickel & Beitel
Collection locality and voucher
UNITED STATES. Arizona: Cochise Co., W wall of Copper Canyon in the Huachuca Mts.,
W 458 (UT), Huachuca Mts., Garden Canyon, Y 84-08 (IND, UT).
UNITED STATES. Arizona: Santa Cruz Co., Pajarito Mts., Alamo Canyon, W 292 (ASC).
UNITED STATES. Arizona: Black Hills, S side of Chasm Creek, W 207 (ASC, UT); N
Fork of Fay Canyon, W 318 (ASC, UT).
[Vol. 90
December 2003]
TABLE 1.
Continued.
Genus
Taxon
Chromosome
count
Mode of
reproduction
Collection locality and voucher
n 5 30
S
*N. sulphurea (Cav.) J. Smith
n 5 30
S
N. trichomanoides (L.) Desv. var. subnuda Jenm.
n 5 60
S
n 5 29
S
P. breweri D. Eaton
n 5 29
S
P. glabella Mett. ex Kuhn subsp. simplex (Butters) Löve & Löve
**P. intermedia Mett. ex Kuhn
n 5 2n 5 116
A
n 5 2n 5 116
A
n 5 29
S
MEXICO. Tamaulipas: SW of Cd. Victoria along Mex. Route 101, WYR 490 (COLO, MO,
NY, UC, UT).
n 5 60
S
n 5 30
S
UNITED STATES. Arizona: Gila Co., Mazatzal Mts., S wall of Barnhardt Canyon, W &
Morefield 447 (MO, UT); Graham Co., Pinaleno Mts., SE side of Jacobson Canyon, WY
773 (NY, UC, UT).
UNITED STATES. California: Tehama Co., SW corner of Ponderosa Sky Ranch housing
development, R & Wolf 753 (UT).
n 5 30
S
n 5 30
S
PELLAEA sect. PELLAEA (I)
P. andromedifolia (Kaulf.) Fée
PELLAEA sect. PELLAEA (II)
P. notabilis Maxon
PENTAGRAMMA
**P. triangularis (Kaulf.) Yatskievych, Windham & Wollenweber subsp. maxonii (Weath.)
Yatskievych, Windham & Wollenweber
P. triangularis (Kaulf.) Yatskievych, Windham
& Wollenweber subsp. semipallida (J. Howell) Yatskievych, Windham & Wollenweber
P. triangularis (Kaulf.) Yatskievych, Windham
& Wollenweber subsp. triangularis
P. triangularis (Kaulf.) Yatskievych, Windham
& Wollenweber subsp. viscosa (Nutt. ex D.
Eaton) Yatskievych, Windham & Wollenweber
a
UNITED STATES. California: Orange Co., Santa Ana Mts., small tributary of Hot Spring
Canyon, W 711 (NY, UT).
UNITED STATES. Nevada: Clark Co., Spring Mts., trail to Charleston Peak, Fisher 1786
(UNLV); Utah: Cache Co., Bear River Range, SW side of Tony Grove Lake, W & M.J.
Windham 91-239 (MO, UT).
UNITED STATES. Arizona: Coconino Co., SW side of the Rio de Flag in Flagstaff, W 192
(ARIZ, ASC).
UNITED STATES. Arizona: Gila Co., Sierra Ancha, Devil’s Chasm, YW & Hevly 81-308
(ASC).
UNITED STATES. California: Los Angeles Co., N of Azusa along West Fork of the San
Gabriel River, W 98-101 (UT), along Arroyo Sequit in the Santa Monica Mts., W 98-108
(UT); Orange Co., along tributary of Hot Spring Canyon in the Santa Ana Mts., W 98096 (UT); San Luis Obispo Co., SW corner of Avila Rd. & Hwy. 101, N of Pismo
Beach, R 870 (UC); Trinity Co., Gray’s Falls Campground along Hwy. 299 and Trinity
River, R & Wolf 754 (UT); Oregon: Lane Co., above Sea Lion Caves along Route 101,
WH & Paris 836 (UT).
UNITED STATES. California: San Diego Co., along San Diegito River WSW of Lake
Hodges Dam, W 857 (UT); SW of Rancho Bernardo along Black Mtn. rd. in La Jolla
Valley, W 98-084 (MO, UT)
STUDIES OF CHEILANTHOID FERNS
*N. schaffneri (Fourn.) Underw. ex Davenp.
MEXICO. Tamaulipas: SW of Cd. Victoria along Mex. Route 101, WYR 491 (UT).
MEXICO. Oaxaca: N of San Pedro Juchitengo along Mex. Route 131, WYR 542 (ARIZ,
BRY, COLO, GH, MO, UC, US, UT).
MEXICO. Oaxaca: c. 26 km SE of Huajuapan de León along Mex. Route 190, WYR 526
(MO, UT).
MEXICO. Tamaulipas: c. 10 km NE of Mier y Noriega along dirt rd. to El Gallito and La
Cardona, WYR 488 (UT).
JAMAICA. Middlesex Parish: vicinity of Arthur’s Seat, about 5.3 km W of Crofts Hill, R
& Trapp 860 (UT).
YATSKIEVYCH—CHROMOSOME
S
S
AND
n 5 30
n 5 30
WINDHAM
N. rigida Davenp.
*N. rosei Maxon
Base numbers reported in literature conflicting or imprecise; see Results and Discussion.
1793
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[Vol. 90
Figs. 1–7. Chromosomes of cheilanthoid ferns at meiosis I. Scale bars 5 5 mm. 1. Argyrochosma dealbata, n 5 27. 2. A. limitanea subsp. limitanea, n 5
81. 3. A. microphylla, n 5 27. Arrow identifies nucleolus. 4. Cheilanthes feei, n 5 90. Arrows identify nucleoli. 5. C. arizonica, n 5 90. Arrows identify
nucleoli. 6. C. tomentosa, n 5 90. Arrows identify overlapping chromosomes. 7. C. eatonii, n 5 90.
December 2003]
WINDHAM
AND
YATSKIEVYCH—CHROMOSOME
Astrolepis—Until recently, the star-scaled cloak ferns were
assigned to either Notholaena (Tryon, 1956; Lellinger, 1985)
or Cheilanthes (Mickel, 1979; Tryon and Tryon, 1982). However, members of this group have a unique combination of
morphological features that led Benham and Windham (1992)
to treat them as a distinct genus. The data presented in Table
1 augment reports by Benham and Windham (1992) and Benham (1992) for A. cochisensis (subspp. arizonica and chihuahuensis), A. sinuata subsp. mexicana, and A. windhamii. They
also corroborate earlier approximate counts for A. cochisensis
subsp. cochisensis (as Notholaena cochisensis in Knobloch
and Tai, 1978) and A. integerrima (as N. integerrima in Knobloch et al., 1973). All but one recognized taxon (the Mexican
species A. beitelii) have now been counted, suggesting that the
base number of the group is uniformly x 5 29. This character
distinguishes members of the segregate genus Astrolepis from
all species of Notholaena sensu stricto (s.s.) (x 5 30; discussed
later) and the majority of those assigned to Cheilanthes (also
x 5 30). The base number of x 5 29 is shared with Pellaea,
some elements of which appear as the sister group of Astrolepis in the molecular analyses of Gastony and Rollo (1998).
Bommeria—The only previous report for B. elegans (as
Hemionitis elegans in Haufler and Soltis, 1986) is based on
our work and is repeated here because the original citation
lacks voucher information. Studies on this group also supported earlier counts for B. hispida (Smith, 1974; Gastony and
Haufler, 1976) and B. pedata (Gastony and Haufler, 1976). All
species assigned to this genus have now been studied chromosomally, and they consistently have a base number of x 5
30.
Cheilanthes—With more than 150 species worldwide
(Tryon and Tryon, 1982), Cheilanthes is, by far, the largest
genus of cheilanthoid ferns. Because the group is very diverse
morphologically, studies emphasizing different characters have
produced very different classification schemes. For purposes
of this discussion, we have chosen the infrageneric classification proposed by Tryon and Tryon (1982), which specifically addresses the diversity of forms found in the Americas.
This classification divides the New World species of Cheilanthes among 10 informal species groups, five of which are represented in our sample. A number of morphologically isolated
species could not be accommodated into this scheme, and
these were treated separately as taxa of uncertain affinity. Each
of these groups are next discussed individually.
Cheilanthes (‘‘brandegei group’’)—Our study yielded a single chromosome count for this species group. It was a first
report for the Mexican endemic C. aurea, a sexual diploid with
n 5 30. Our survey of published records indicates that none
of the other taxa listed by Tryon and Tryon (1982) as belonging to this group have been counted.
Cheilanthes (‘‘fraseri group’’)—New counts for this group
include a first report for the Mexican endemic C. longipila.
This species appears closely related to the more northern taxa
C. parryi and C. lanosa, and all three share a diploid chromosome number of n 5 30. The data presented in Table 1
also corroborate earlier published counts for C. bonariensis
(as Notholaena aurea in Knobloch et al., 1973) and C. newberryi (as N. newberryi in Knobloch, 1967). There are conflicting reports for C. feei, the only other member of the C.
STUDIES OF CHEILANTHOID FERNS
1795
fraseri group included in this study. Although Knobloch
(1967) reported a chromosome number of 2n 5 87 for this
species, collections from two separate populations in Arizona
clearly show n 5 2n 5 90 (Fig. 4). Given the lack of photographic documentation for Knobloch’s count, the sole report
of x 5 29 in this group must be considered suspect. The data
at hand suggest that the base number of the C. fraseri group
is uniformly x 5 30. Nevertheless, a broader sample of this
large, morphologically diverse group will be necessary to confirm this hypothesis.
Cheilanthes (‘‘marginata group’’)—A first report for C. cuneata indicates that it is an apogamous triploid with n 5 2n
5 90. The only previous record for this species group was a
count of 2n 5 87–90 on a plant identified as C. pyramidalis
by Knobloch et al. (1975). Reexamination of the voucher specimen deposited at MSC revealed that this collection represents
the taxon now known as C. arizonica. Three different populations of this species in Arizona (including the type locality
in Ramsey Canyon) yielded counts of n 5 2n 5 90 (Fig. 5).
Although most of the species assigned to this group by Tryon
and Tryon (1982) have not been studied, the available data
support a base number of x 5 30.
Cheilanthes (‘‘microphylla group’’)—Our study yielded the
first chromosome counts for C. horridula, which encompasses
a sexual diploid cytotype showing n 5 29 and a sexual tetraploid with n 5 58. Although this species was assigned to
the C. myriophylla group by Tryon and Tryon (1982), Reeves
(1979) argued that its morphological affinities lay with C. alabamensis, a core member of the C. microphylla alliance. Our
counts of n 5 29 and n 5 58 for C. horridula appear to
support Reeves’ classification of this taxon, given that the C.
microphylla group is the only assemblage of New World Cheilanthes species with a consistent base number of x 5 29. The
current study also confirmed previous reports based on x 5
29 for C. alabamensis (Knobloch, 1967; Knobloch et al.,
1975) and C. aemula (Knobloch et al., 1975).
There is one conflicting report concerning the chromosome
number of C. aemula, which was given as n 5 30 by Knobloch (1967). However, there is good reason to doubt the validity of this count because the report of 2n 5 58 by Knobloch
et al. (1975) is derived from the same collection. The two
populations of C. aemula included in this study derive from
the same area of northeastern Mexico and clearly show n 5
29 (Fig. 11).
Most of the species included in the C. microphylla group
by Tryon and Tryon (1982) have now been counted, and all
show a base number of x 5 29. This is in sharp contrast to
the majority of Cheilanthes species, which consistently exhibit
x 5 30. These chromosomal differences are accompanied by
morphological distinctions that suggest a close relationship between the C. microphylla group and the genus Pellaea (Cranfill, 1980). Further work will be necessary to ascertain whether
this species group should remain in Cheilanthes, be transferred
to Pellaea, or be recognized as a distinct genus.
Cheilanthes (‘‘myriophylla group’’)—A first report for C.
lindheimeri indicates that this taxon is an apogamous triploid
with n 5 2n 5 90. The data presented in Table 1 also corroborate earlier published counts for C. covillei (Smith, 1974;
Schaack et al., 1984), C. fendleri (Windham, 1983; Windham
and Schaack, 1983), and C. wootonii (Windham, 1983). All
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[Vol. 90
Figs. 8–12. Chromosomes of cheilanthoid ferns at meiosis I. Scale bars 5 5 mm. 8. Cheilanthes lendigera, n 5 60. 9. C. villosa, n 5 90. Arrows identify
overlapping chromosomes. 10. C. yavapensis, n 5 120. 11. C. aemula, n 5 29. 12. C. wrightii, n 5 30.
remaining species of the C. myriophylla group included in this
study are subject to conflicting reports in the literature and are
next discussed individually.
Cheilanthes tomentosa has been counted repeatedly, and the
majority of published reports indicate that this species is an
apogamous triploid with n 5 2n 5 90 (Knobloch, 1966, 1967;
Whittier, 1970; Knobloch et al., 1975). The conflict in this case
involves counts of 2n 5 87 and n 5 c. 89 published by Wagner et al. (1970) and Lloyd (1966), respectively. The first reference clearly states that the chromosome numbers listed are
based upon the literature and are not new counts. Because
there are no other records of 2n 5 87 for C. tomentosa, this
report is considered erroneous. Aside from being an approximate count that could be reinterpreted as n 5 90, Lloyd’s
report is also suspect because this species is not known to
occur in the northern Trans-Pecos region of Texas (Correll,
1956). Attempts to locate the voucher specimen for Lloyd’s
count at UC were unsuccessful (A. R. Smith, University of
California, personal communication), and the report of n 5 c.
89 for C. tomentosa should therefore be set aside because the
identification cannot be confirmed. With these two reports excluded, all documented chromosome counts for C. tomentosa
are n 5 2n 5 90, a number confirmed by the three populations
included in this study (Fig. 6).
Previous reports for Cheilanthes eatonii (here circumscribed
to include C. castanea following Reeves, 1979) include counts
of 2n 5 87 (Lloyd, 1966; Knobloch et al., 1975) and n 5 2n
5 90 (Knobloch et al., 1975; Benham and Schaack, 1988). As
was the case with C. tomentosa, the count by Lloyd (1966) is
approximate and the identification of the collection cannot be
confirmed because there is no voucher available at UC. As
such, this report does not provide strong evidence for a base
number of x 5 29 in C. eatonii. The same is true of the 2n
5 87 report by Knobloch et al., who cast doubt on their own
count by stating ‘‘. . . we cannot say with certainty whether
our first count of 2n 5 87 was wrong or whether there are
two cytotypes in C. castanea’’ (Knobloch et al., 1975, p. 651).
The three collections analyzed during this study (which included both eatonii and castanea morphs) provided an abundance of clear preparations showing n 5 2n 5 90 (Fig. 7).
Knobloch et al. (1975) reported a count of 2n 5 109 6 3
for Cheilanthes lendigera and suggested that this species
might be a tetraploid based on x 5 29. Our studies confirm
that C. lendigera is indeed tetraploid, but the photos clearly
indicate that the chromosome number is n 5 60 (Fig. 8), not
2n 5 116 as hypothesized by previous authors. A similar situation was encountered in C. villosa, for which Knobloch
(1967) reported a count of 2n 5 87. Collections from two
populations of C. villosa from southern Arizona indicate that
the chromosome number of this species is n 5 90 (Fig. 9).
December 2003]
WINDHAM
AND
YATSKIEVYCH—CHROMOSOME
The final disputed count in the Cheilanthes myriophylla
group involves a report by Knobloch (1967) of 2n 5 116 in
a collection identified as C. wootonii. This species subsequently proved to be an apogamous triploid with n 5 2n 5 90
(Windham, 1983; Table 1). Reexamination of the voucher
specimen for Knobloch’s tetraploid count (deposited at MSC)
revealed that this collection represents C. yavapensis, a species
initially segregated from C. wootonii by Reeves (1979). Isozyme studies indicate that C. yavapensis is a distinct allopolyploid species that probably originated through hybridization
between C. lindheimeri and C. covillei (Gastony and Windham, 1989). With both parental taxa having chromosome
counts based on x 5 30 (Table 1), it is highly unlikely that C.
yavapensis deviates from that base number. In agreement with
three earlier counts of C. yavapensis by Windham (1993a), the
two populations surveyed for this study were composed of
apogamous tetraploids showing n 5 2n 5 120 (Fig. 10).
Reeves (1979) reviewed the available chromosome data for
the C. myriophylla group (5 subg. Physapteris) but was unable to draw any conclusions concerning the base number because of the many conflicting reports. With the addition of the
counts listed in Table 1, a clearer picture is emerging. Nearly
60% of the species included in the C. myriophylla group have
now been studied chromosomally, all of which have yielded
counts based on x 5 30. Chromosome counts based on x 5
29 have been attributed to nearly half of these species by previous authors, but these earlier reports appear to be erroneous.
Samples of all but two of the taxa previously reported as x 5
29 were acquired for this study, and the resultant counts were,
without exception, based on x 5 30. The only species missing
from our sample were C. chipinquensis and C. myriophylla.
Knobloch and Lellinger (1969) attributed a chromosome number of 2n 5 58 to the former, and Lloyd (1966) reported a
count of n 5 2n 5 87 for the latter. However, Knobloch et al.
(1975) provided micrographs for these species that showed 2n
5 60 and 2n 5 c. 90, respectively. Considering that all recent,
photographically documented counts are based on x 5 30, we
conclude that this is the true base number of the C. myriophylla group.
Cheilanthes (‘‘incertae sedis’’)—This group represents a
‘‘dumping ground’’ for species whose relationships to other
members of the genus are unclear. Included are first reports
for C. brachypus, C. lozanii var. seemanii, and C. pringlei, all
of which proved to be sexual diploids with n 5 30. Published
counts for C. gryphus (Mickel, 1987) and C. subcordata (as
Hemionitis subcordata in Haufler and Soltis, 1986) are based
on our work and are repeated here because the original citations lack voucher information. An earlier report of n 5 30
for C. leucopoda (Knobloch, 1967) was corroborated by our
sampling. Although Knobloch (1966) reported a count of 2n
5 58 for C. wrightii, samples from two populations close to
his collection locality in southern Arizona clearly showed n 5
30 (Fig. 12). Given the morphological diversity represented in
this group, it is unlikely that these species are closely related.
However, all seven had a base number of x 5 30, a number
shared with the majority of species assigned to Cheilanthes.
Cheiloplecton—Although included in Pellaea by many earlier authors, Cheiloplecton is recognized as a distinct genus by
Smith (1981) and Mickel and Beitel (1988). It is one of the
last cheilanthoid genera to be studied chromosomally, and the
count presented here for C. rigidum var. lanceolatum is ap-
STUDIES OF CHEILANTHOID FERNS
1797
parently the first report for the genus. This taxon, which is
endemic to southern Mexico, proved to be an apogamous triploid with n 5 90. This isolated chromosome count seems to
support assertions by Smith (1981) and Mickel and Beitel
(1988) that Cheiloplecton is more closely related to Cheilanthes (with x 5 30) than it is to Pellaea (with x 5 29).
Hemionitis—A single count for H. palmata from Jamaica
supports earlier determinations by Wagner (1963), Walker
(1966, 1985), Smith and Mickel (1977), and others. With
counts available for the majority of species, it appears that the
chromosome base number of Hemionitis (including Gymnopteris following Ranker, 1989) is uniformly x 5 30.
Mildella—The apogamous triploid count of n 5 90 presented here for M. intramarginalis var. serratifolia is the first
report for the genus in the Americas and suggests a base number of x 5 30. However, published chromosome counts for
the Asian species M. henryi (Tsai and Shieh, 1983) and M.
nitidula (as Pellaea nitidula in Verma and Goloknath, 1967)
are consistently based on x 5 29. Species from the two regions
differed substantially in spore ornamentation, and the chromosomal data seem to support the hypothesis (Tryon and
Tryon, 1982) that Asian and American species of Mildella
represent separate evolutionary lines.
Notholaena—The typification and circumscription of this
genus have been contentious topics in systematic pteridology
(Yatskievych and Smith, in press). Studies by Tryon and Tryon
(1982) and Windham (1993b) revealed that the American taxa
traditionally assigned to Notholaena represent at least four distinct evolutionary lines. With the transfer of several species
groups to Cheilanthes (Tryon and Tryon, 1982) and the recognition of Argyrochosma (Windham, 1987) and Astrolepis
(Benham and Windham, 1992) as separate genera, the remainder of the American species form a coherent, monophyletic
group. However, the correct name for this group is in dispute
because Notholaena has been lectotypified by several authors
citing three different type species. Following Yatskievych and
Smith (in press), we accept the first lectotypification based on
N. trichomanoides, a member of the monophyletic group mentioned earlier. The second and third lectotypifications (the last
favored by some European workers, e.g., Pichi-Sermolli, 1983,
1989) are based on Old World taxa unrelated to the species
herein called Notholaena.
This group has received very little attention from cytotaxonomists, and our study yielded first reports for 10 taxa. Notholaena bryopoda, N. candida, N. lemmonii, N. rosei, N. schaffneri, and N. sulphurea all proved to be sexual diploids with n
5 30. Both N. aschenborniana and N. grayi subsp. grayi
yielded counts of n 5 2n 5 90, indicating that they are apogamous triploids. An even higher ploidy level was encountered
in N. californica subsp. californica, which proved to be an
apogamous pentaploid with n 5 2n 5 150. First counts for
N. neglecta revealed that it encompasses two ploidy levels; a
sexual diploid cytotype with n 5 30 and an apogamous triploid with n 5 2n 5 90. Our study also corroborated earlier
counts for N. copelandii and N. greggii (Benham and Schaack,
1988), N. galeottii and N. rigida (Knobloch et al., 1973), and
N. trichomanoides var. subnuda (as forma subnuda in Walker,
1973). Chromosome counts are now available for 16 of the c.
25 species included in Notholaena s.s., all of which exhibit a
base number of x 5 30.
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Pellaea—Tryon and Tryon (1982) divided this genus into
four ‘‘sections,’’ two of which are restricted to the Old World,
with a third confined to tropical South America. The biogeographical, morphological, and chromosomal differences
among these ‘‘sections’’ suggest that most are worthy of generic recognition, a conclusion supported by the molecular
data of Gastony and Rollo (1998). All of the taxa included in
this report represent section Pellaea, which has been very well
studied chromosomally. As such, the only new count represents a previously unknown apogamous tetraploid cytotype of
P. intermedia showing n 5 2n 5 116.
Within the group commonly known as the light-stipe cliff
brakes, previous reports of n 5 29 for Pellaea andromedifolia
(Tryon, 1968; Smith, 1974) and P. notabilis (Tryon, 1972)
were confirmed. Among the species with dark stipes and concolorous rhizome scales, this study verified earlier counts for
P. glabella subsp. simplex (as var. simplex in Tryon and Britton, 1958) and P. breweri (Tryon and Britton, 1958). In the
case of the latter species, a photograph of the Nevada count
was published previously by Windham and Haufler (1986), but
the collection is included here because the original report
lacked voucher information.
Pentagramma—Studies by Yatskievych et al. (1990) revealed that the genus Pityrogramma sensu lato (s.l.) comprised
two distinct evolutionary lines differing in several important
features (including chromosome base number) that suggested
they belonged to different tribes within the family Pteridaceae.
Subsequent molecular analyses by Gastony and Rollo (1998)
have shown that the tropical members of Pityrogramma (including the type species) do not belong to subfamily Cheilanthoideae. Although Pityrogramma is thus excluded from consideration here, it is appropriate to discuss the temperate taxa
that Yatskievych et al. (1990) transferred to the genus Pentagramma. This group was strongly supported as a member of
Cheilanthoideae in the rbcL analyses of Gastony and Rollo
(1998).
As currently defined, Pentagramma comprises two species,
one of which (P. pallida) is endemic to north-central California, while the other (P. triangularis) ranges over much of
western North America and is divisible into several subspecies. Although California populations of P. triangularis have
been well studied chromosomally, the Sonoran Desert taxon
(subsp. maxonii) has received little attention. Thus, it is not
surprising that our survey revealed an unreported sexual tetraploid cytotype in subsp. maxonii showing n 5 60. The only
previous report for this taxon was a diploid count of n 5 30
published by Yatskievych et al. (1990).
Previous reports of a diploid cytotype of Pentagramma triangularis subsp. semipallida (as Pityrogramma triangularis
var. semipallida in Smith, 1980) from California are corroborated by a new record from Tehama County. A series of
counts for Pentagramma triangularis subsp. triangularis from
California and Oregon supports earlier records (as Pityrogramma triangularis in Alt and Grant, 1960; Smith et al., 1971;
Smith, 1974) of a widespread diploid cytotype with n 5 30.
Two additional determinations for subsp. viscosa from San Diego County, California, agree with previous reports (as Pityrogramma viscosa in Alt and Grant, 1960) from the same region. With chromosome counts available for all currently recognized taxa, it is clear that the base number of Pentagramma
is consistently x 5 30.
Fig. 13. Chromosome base numbers and phylogenetic relationships of
genera and species groups included in this study (phylogeny based on rbcL
tree from Gastony and Rollo, 1998). Numbers above branches are bootstrap
percentages. Superscripts after generic names indicate alternative classification by Tryon and Tryon (1982). a included in Cheilanthes; b included in Notholaena; c included in Pityrogramma.
Stability and evolution of chromosome base numbers in
cheilanthoid ferns—Our data set, comprising the largest single block of cheilanthoid chromosome counts published to
date, provides important new insights into the stability and
evolution of base numbers in the group. Whereas earlier attempts at synopsis (e.g., Knobloch et al., 1975; Reeves, 1979)
were confounded by seemingly random variations in base
number, our study reveals remarkable stability comparable to
that observed in other fern groups (Britton, 1974). We present
a total of 131 counts representing 75 taxa of cheilanthoid ferns
from the western United States and Mexico. The 16 species
groups represented here do not have a single case of withingroup variation in base number. The genus Cheilanthes s.l. has
some variability, with x 5 29 in the C. microphylla group and
x 5 30 in all other species sampled. However, Cheilanthes is
highly polyphyletic (Gastony and Rollo, 1998), and the distinctive nature of the C. microphylla group suggests that it
may be worthy of generic recognition.
In addition to being a stable attribute of species groups
among the cheilanthoid ferns we studied, chromosome base
number appears to be a relatively conservative trait in the evolution of the subfamily. Figure 13 shows Gastony and Rollo’s
(1998) rbcL phylogeny for the group, pruned to show only the
genera and species groups included in our study. From this, it
is evident that x 5 30 is the plesiomorphic character state for
subfamily Cheilanthoideae. Although restricted to the higher
December 2003]
WINDHAM
AND
YATSKIEVYCH—CHROMOSOME
branches of the tree, taxa with x 5 29 occur in two separate
clades and do not appear to form a monophyletic group. A
broader survey of the Pteridaceae as a whole indicates that x
5 29 has several independent origins in the family (Gastony
and Yatskievych, 2001).
The topology of Gastony and Rollo’s tree suggests two possibilities for the origin of x 5 29 among the taxa included in
our data set. Derived late in the evolutionary history of subfamily Cheilanthoideae, x 5 29 could have a single, unique
origin along the branch (bootstrap 62) leading to the Argyrochosma/Cheilanthes myriophylla clade, as suggested by Gastony and Yatskievych (2001). This hypothesis requires a reversal to x 5 30 along the branch (bootstrap 52) leading to
the C. myriophylla alliance and its sister clade. Alternatively,
x 5 29 may have originated twice, once along the branch
leading to the C. microphylla group and again near the base
of the Pellaea/Astrolepis clade. This second origin could have
occurred either on the branch (bootstrap 88) immediately subtending Pellaea and Astrolepis or on the branch (bootstrap 85)
below Argyrochosma. In the first case, the unique base number
of Argyrochosma is derived directly from x 5 30; in the second, x 5 29 represents an intermediate step in a process of
descending aneuploidy ultimately leading to x 5 27.
The fact that we can even propose hypotheses for the origin
of x 5 29 in subfamily Cheilanthoideae means that our understanding of the group is improving. However, much more
remains to be done. Nearly half of the taxa assigned to Argyrochosma and Notholaena s.s. remain uncounted, and the
sampling of Cheilanthes is woefully inadequate. The type species of the genus (C. micropteris) has not been subject to chromosomal or molecular analyses, so we are unable to determine
which branch of Gastony and Rollo’s (1998) phylogenetic tree
properly bears the name Cheilanthes. Additional potentially
erroneous counts remain ensconced in the literature, and the
chromosome numbers of most South American taxa are unknown.
As we work to fill these gaps in our knowledge of cheilanthoid ferns, the accuracy of our observations must be paramount. Inaccurate counts are the bane of the cytogenetic literature because it is nearly impossible to disprove an erroneous report. Photographic documentation is essential, especially
among the homosporous ferns with high base numbers. No
one has described the situation more clearly than Irene Manton, whose work provides the foundation and inspiration for
modern fern cytogenetics. As Manton (1950, p. ix) said, ‘‘In
a group like the Pteridophyta, where the technical difficulties
are so great that it has been my unfortunate lot to have to
correct errors in the work of almost every previous investigator, the attainment of accuracy has been a primary task without which no valid general conclusions could have been
drawn. For this reason the use of photography has assumed a
special importance. . . what cannot be photographed cannot be
used as evidence.’’
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