A systematic histological study of palm fruits. IV. Subtribe Oncospermatinae (Arecaceae)

Pericarp histology in the Oncospermatinae reveals distinctive characters at the generic level but no unique characters at the subtribal level. Pericarp structure is diverse but parallels the diversity found in other subtribes of the Areceae. The subtribe appears to be divisible into two distinct groups: one in which sclereids alone provide the primary protective barrier in the outer fruit and one in which fibrous bundles, some-times in combination with brachysclereids, form the outer barrier. This division of the subtribe supports similar conclusions derived from morphological data.     

A systematic histological study of palm fruits. V. Subtribe Archontophoeniciae (Arecaceae)

Pericarp histology in the Archontophoenicinae provides little to characterize the subtribe as a whole, revealing instead two separate trends with parallels in other subtribes of the Areceae. The data support a close relationship among the three genera occurring in New Caledonia:Chambeyronia, Actinokentia, andKentiopsis, in which there is a complex endocarp consisting of short, oblique fibrous bundles embedded in a thick mantle of brachysclereids, and a loose endocarp of heavily fibrous, flattened vascular bundles adjacent to a relatively thin locular epidermis. The data also support a close relationship between the two genera of the New Zealand/Tasman Sea region:Hedyscepe andRhopalostylis, in which the pericarp is more or less fibrous throughout, with purely fibrous bundles in the outer pericarp and heavily fibrous vascular bundles in the inner pericarp. These results confirm relationships revealed by other morphological data.Archontophoenix appears to be most like the New Caledonian genera in its pericarp structure, with a similar mantle of short fibrous bundles embedded in a a mantle of brachysclereids in the outer pericarp, although it differs significantly in other aspects of morphology and anatomy.     

A systematic histological study of palm fruits. III. Subtribe Iguanurinae (Arecaceae)

This study represents a preliminary sampling of the pericarp histology of the subtribe Iguanurinae (tribe Areceae, subfamily Arecoideae) of the family Arecaceae. At least one sample from each of the 27 recognized genera was examined and illustrated with a line drawing. This sampling serves to characterize fruit structure in the subtribe as a whole, to illustrate the diversity of pericarp adaptations found in the subtribe, to characterize the monotypic genera, to provide hypotheses about the characterization of the larger genera, and to test existing phylogenetic hypotheses about the Iguanurinae. There are no unique tissues present in the pericarp in this subtribe, but genera can be readily characterized by unique combinations and distributional patterns in common tissues. These patterns, and some prominent evolutionary trends, parallel those in related subtribes of Areceae, such as the Ptychospermatinae and Arecinae. Significant in this subtribe is variation in the distribution of tanniniferous cells, raphide-bearing cells and brachysclereids, in the sculpturing of the seed and the locular epidermis, in the thickness of the locular epidermis, in the thickness of the fibrous vascular bundle sheaths, and especially in the number, orientation and distribution of nonvascular fibrous bundles. One major trend is the formation of systems of separate fibrous bundles and their progressive displacement toward the outer layer of the fruit, where a complex exocarp may form. The diversity of pericarp structure in the Iguanurinae is far greater than in the two subtribes previously studied.     

A systematic histological study of palm fruits. VI. Subtribe Linospadicinae (Arecaceae)

The pericarp structure of representative species of the four genera of the subtribe Linospadicinae is described and compared. Tissues found in the pericarp of this group are similar to those found in other subtribes of the Areceae, with no characters unique to the subtribe and nothing to suggest its closest affinities. The four genera, as well as each species examined, do show distinctive pericarp features, however.Laccospadix andLinospadix are similar, both with a single series of fibrous, bundles and an outer series of prominent raphide-bearing cells dominating the pericarp. In bothHowea andCalyptrocalyx, a complex exocarp forms from a series of fibrous bundles and brachysclereids, but each genus has other distinctive characters.Howea has vascular bundles in the exocarp zone, an outer series of raphide-bearing cells, and a conspicuously thickened locular epidermis. Based on a limited sample of four species, raphide-bearing cells appear to be always interior to the exocarp inCalyptrocalyx, and the locular epidermis is thin.     

A systematic histological analysis of palm fruits VII. The Cyrtostachydinae (Arecaceae)

Fruit specimens representing five taxa of the genusCyrtostachys were examined histologically in order to characterize the pericarp anatomy of the monogeneric subtribe Cyrtostachydinae (tribe Areceae, subfamily Arecoideae), as part of an ongoing survey of the family. The pericarp in this genus can be characterized by a combination of papillate epidermis, heavy layer of tanniniferous/pigmented cells below the epidermis, a system of vascular bundles with thick fibrous sheaths with purely fibrous bundles frequently above and below, absence of brachysclereids, and a very thin sclerified locular epidermis. On the basis of pericarp structure alone, the genus might be most closely related to theGronophyllum alliance of the subtribe Arecinae. This diverges somewhat from the hypothesis of relationship with theAreca group of the Arecinae resulting from two DNA-based phylogenetic studies, and even further from the hypothesis of relationship withIguanura suggested by another DNA-based phylogenetic study.     

Nuclear DNA Amounts in Palms (Arecaceae)

Nuclear DNA amounts are reported for 83 species and 53 genera of palms, covering all of the six subfamilies. 4C DNA contents range between 3.89 and 55.62 pg in diploids, showing an approximate 14.3-fold variation in genome size. Polyploids have DNA contents of up to 156.40 pg/4c which demonstrates a 40.2-fold variation. Diploids with high DNA contents occur in three subfamilies of palms (Coryphoideae, Calamoideae, Arecoideae), and seem to be further restricted to particular tribes or subtribes (Thrinacinae, Borasseae, Lepidocaryeae, Caryoteae, some subtribes of Areceae). Palms from the subfamilies Nypoideae and Phytelephantoideae have the lowest DNA amounts, followed by the Phoeniceae and the Corypheae: Livistoninae from the subfamily Coryphoideae. Although DNA amounts in some genera and subtribes are usually constant, e.g., in Phoenix, Phytelephas, the Livistoninae, Dypsidinae, diploid Butiinae), considerable variation occurs at the diploid level in some large and apparently actively evolving genera such as Chamaedorea, Pinanga, Cenoma and possibly Bactris. Formaldehyde fixation is recommended for palms, as conventional ethanol-acetic acid fixation has proved to be unsuitable for DNA estimation of Feulgen-stained nuclei by microdensitometry, since it can lead to errors up to 2.5-fold in extent. Chromosome counts are reported for 72 of the species studied, of which 42 are new.     

The occurrence and structure of apparently bisexual flowers in the date palm, Phoenix dactylifera L. (Arecaceae)

Individuals of Phoenix dactylifera L. have expanded pistillodes or pseudocarpels in staminate flowers. These pseudocarpels are located in the centre of the male flowers and are surrounded by stamens. The gynoecium has the characteristic three carpellate arrangement commonly found in female date palm flowers. Pseudocarpels from male flower buds can expand into parthenocarpic fruit. Histology of the expanded pistillodes or pseudotarpels is similar to that of normal carpels from pistillate plants. These pseudocarpels lack ovules. Nutrient medium containing 10 mg 1^-1 of 2,4-dichlorophenoxyacetic acid or p-chlorophenylacetic acid and 0.3% activated neutralized charcoal enhanced the development and outgrowth of the pseudocarpels of cultured male flowers.     

A phylogenetic analysis of palm subtribe Archontophoenicinae (Arecaceae) based on 14 DNA regions

Subtribe Archontophoenicinae belongs to Areceae, the largest of all palm tribes. It includes 15 species distributed in five genera, all found in the south‐western Pacific Region. Archontophoenicinae are rather homogeneous in morphology, making phylogenetic relationships problematic to reconstruct using morphological characters. In this study we investigated phylogenetic relationships in Archontophoenicinae based on all 15 species of the subtribe, using a combination of nine plastid and five nuclear DNA sequence markers. The plastid regions used were the coding rbcL, matK, ndhF and rpoC1 (exon 2) and the non‐coding rps16 intron, atpF‐atpH, psbK‐psbI, trnL‐trnF and trnQ‐rps16. The nuclear regions used were AG1, BRSC, ITS2, PRK and RPB2, which have all proved useful in palm systematics. We compared the phylogenetic hypotheses resulting from the plastid versus nuclear datasets, and combined both datasets to retrieve as much phylogenetic information as possible. Our results strongly support a clade composed of all species of Archontophoenix, Actinokentia, Chambeyronia and Kentiopsis, but raise the question of whether Actinorhytis, the fifth genus, should remain in Archontophoenicinae. Interspecific relationships in ‘core Archontophoenicinae’ still remain incompletely resolved, despite the gene and taxon sampling being substantially greater than in previous studies, and question the monophyly of the New Caledonian genera Chambeyronia and Kentiopsis. © 2014 The Linnean Society of London, Botanical Journal of the Linnean Society, 2014, 175 , 469–481.     

Functional and historical drivers of leaf shape evolution in palms (Arecaceae)

Aim

Leaves display a remarkable variety of shapes, each with potential ecological advantages in specific climates. While the relations between leaf shape and either climate or height have been relatively well studied in eudicots, the macroecological drivers of shape remain poorly known in monocots. Here, we investigated the associations between climate and plant height with the evolution of leaf shape in a clade with high species and morphological diversity.

Location

Global.

Time period

Cretaceous to contemporary.

Major taxa studied

Palms (Arecaceae).

Methods

We apply a Bayesian phylogenetic mixed model to test for associations between climate and leaf shape (all – entire-leaved, pinnate-dissected, palmate-dissected and costapalmate). We further reconstruct the ancestral leaf shape using multistate speciation and extinction models and compare the frequency of shapes with global temperatures through time.

Results

We find that plant height associates with dissected leaves and that annual precipitation associates with pinnate shapes. The ancestral leaf shape is unclear, but early diversification was dominated by pinnate-dissected palms, which has remained the most species-rich form of leaves throughout palm history.

Main Conclusions

Palms that are tall and live in humid regions are more likely to have pinnate leaves. Through geological time scales, temperature did not play an obvious role in determining leaf shapes. This study contributes to our understanding of how the diversity of leaf shapes is linked to biological and climatic factors.     

Evolution of lamina anatomy in the palm family (Arecaceae)

The unique properties of tree building in Arecaceae strongly constrain their architectural lability. Potentially compensating for this limitation, the extensive diversification of leaf anatomical structure within palms involves many characters whose alternate states may confer disparate mechanical or physiological capabilities. In the context of a recent global palm phylogeny, we analyzed the evolution of 10 such lamina anatomical characters and leaf morphology of 161 genera, conducting parsimony and maximum likelihood ancestral state reconstructions, as well as tests of correlated evolution. Lamina morphology evolves independently from anatomy. Although many characters do optimize as synapomorphic for major clades, anatomical evolution is highly homoplasious. Nevertheless, it is not random: analyses indicate the recurrent evolution of different cohorts of correlated character states. Notable are two surface layer (epidermis and hypodermis) types: (1) a parallel-laminated type of rectangular epidermal cells with sinuous anticlinal walls, with fibers present in the hypodermis and (2) a cross-laminated type of hexagonal cells in both layers. Correlated with the cross-laminated type is a remarkable decrease in the volume fraction of fibers, accompanied by changes in the architecture and sheath cell type of the transverse veins. We discuss these and other major patterns of anatomical evolution in relation to their biomechanical and ecophysiological significance.     

Evaluation of the bromatological potential of seeds and fruits ofSabal Mexicana Mart. (Arecaceae)

This work presents bromatological analyses performed on seeds and fruits of Sabal mexicana Mart.; a comparison with data existent of other palms and some phytochemical data are presented. A discussion of the possible importance of some results obtained and the potential use of this palm is presented

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Evaluacion del potencial bromatologico de semillas y frutos de sabal mexicana, mart. (arecaceae)

Résumé  Este trabajo presenta análisis bromatolólogicos realizados en semillas y frutos de Salbal mexicana Mart. Los resultados se comparan con datos existentes para otras palmas y se presentan algunos datos fitoquimicos; ademús se discute acerca de la posible importancia de algunos de los resultados obtenidos y su uso potential

     

Phylogenetic utility of the nuclear gene malate synthase in the palm family (Arecaceae)

There is currently a shortage of DNA regions known to be useful for phylogenetic research in palms (Arecaceae). We report the development and use of primers for amplifying and sequencing regions of the nuclear gene malate synthase. In palms the gene appears to be single-copy, with exon regions that are phylogenetically informative within the family. We constructed a phylogeny of 45 palms and five outgroup taxa using 428 bp of malate synthase exon regions. We found that some major clades within the family were recovered, but there was a lack of resolution among the genera in subfamilies Arecoideae, Ceroxyloideae, Coryphoideae, and Phytelephantoideae. In a second analysis, malate synthase exon regions totaling 1002 bp were sequenced for 16 palms and two outgroup taxa. There was increased bootstrap support for some groups and for the placement of the monotypic genus Nypa as sister to the rest of the family. A comparison with data sets from noncoding regions of the chloroplast genome indicates that malate synthase sequences are more variable and potentially contain more phylogenetic information. We found no evidence of multiple copies of the malate synthase gene in palm genomes.     

Isolation and characterization of nuclear microsatellite loci in the tropical arboreal palm Oenocarpus bacaba (Arecaceae)

Studies of mating patterns are needed to determine how habitat heterogeneity created by deforestation influences tropical plant populations. Eight microsatellite loci were isolated with a subtractive hybridization method for Oenocarpus bacaba (Arecaceae), a subcanopy palm tree at the Biological Dynamics of Forest Fragments Project, near Manaus, Brazil. Additionally, two heterospecific loci originally developed for the heart palm Euterpe edulis were shown to be variable. Loci averaged 9.6 alleles per locus. Five loci did not fit Hardy–Weinberg expectations with significant deficits of heterozygous genotypes consistent with null alleles. Many loci had high average probabilities of paternity exclusion.     

Isolation of 23 polymorphic microsatellite loci in the Neotropical palm Oenocarpus bataua Martius (Arecaceae)

We report the isolation of 23 microsatellite loci obtained from a (GA)_n‐enriched genomic library of Oenocarpus bataua var. bataua. The average number of alleles per locus, the mean observed and expected heterozygosities for these microsatellite loci revealed a high level of variability. The transferability of the developed markers to other Oenocarpus species and other genera within the Euterpeae tribe was high, except for the Hyospathe genus.     

Commonness of Amazonian palm (Arecaceae) species: Cross-scale links and potential determinants

The mechanisms that cause variation in commonness (abundances and range sizes) of species remain debated in ecology, and a repeatedly observed pattern is the positive relation between local abundances and larger scale range sizes. We used the Amazonian palm species (Arecaceae) to investigate the dependence between and potential determinants of commonness across three (local, landscape, continental) spatial scales. Commonness at the smaller scales (local abundance, landscape frequency) was estimated using data from 57 transects (5 × 500 m) in primary, non-inundated (terra firme) rainforest in a western Amazonian landscape, while commonness at the largest scale (continental range size) was estimated from digitized distribution maps. Landscape frequency was positively related to both local abundance and continental range size, which, however, were not related to each other. Landscape frequency was positively related to topographic niche breadth. Stem height correlated with continental range size and was the only species life-history trait related to any commonness measure. Distance from the study area to a species' range centre did not influence any of the commonness measures. The factors determining commonness in the Amazonian palm flora appear to be scale-dependent, with the unrelated local scale abundance and continental range size probably being controlled by different driving factors. Interestingly, commonness at the intermediate, landscape scale seems linked to both the smaller and the larger scale. Our results point towards topographic niche breadth at the smaller scales and stem height, possibly reflecting species' dispersal potential, at the continental scale as important determinants of commonness.     

Floral structure and development in the monoecious palm Gaussia attenuata (Arecaceae; Arecoideae)

Background and Aims

Sexual dimorphism, at both the flower and plant level, is widespread in the palm family (Arecaceae), in contrast to the situation in angiosperms as a whole. The tribe Chamaedoreeae is of special interest for studies of the evolution of sexual expression since dioecy appears to have evolved independently twice in this group from a monoecious ancestor. In order to understand the underlying evolutionary pathways, it is important to obtain detailed information on flower structure and development in each of the main clades.

Methods

Dissection and light and scanning electron microscopy were performed on developing flowers of Gaussia attenuata, a neotropical species belonging to one of the three monoecious genera of the tribe.

Key Results

Like species of the other monoecious genera of the Chamaedoreeae (namely Hyophorbe and Synechanthus), G. attenuata produces a bisexual flower cluster known as an acervulus, consisting of a row of male flowers with a basal female flower. Whereas the sterile androecium of female flowers terminated its development at an early stage of floral ontogeny, the pistillode of male flowers was large in size but with no recognizable ovule, developing for a longer period of time. Conspicuous nectary differentiation in the pistillode suggested a possible role in pollinator attraction.

Conclusions

Gaussia attenuata displays a number of floral characters that are likely to be ancestral to the tribe, notably the acervulus flower cluster, which is conserved in the other monoecious genera and also (albeit in a unisexual male form) in the dioecious genera (Wendlandiella and a few species of Chamaedorea). Comparison with earlier data from other genera suggests that large nectariferous pistillodes and early arrest in staminode development might also be regarded as ancestral characters in this tribe.     

Comparative floral structure and systematics in the Asian palm genus Rhapis (Arecaceae,Coryphoideae)

A comparative study of the floral structure in the species of the genus Rhapis (Arecaceae, Coryphoideae, Rhapidinae) is presented. Flowers are mainly unisexual, with three sepals, three petals, 6 stamens or staminodes and three carpels or carpellodes. Some evidences of basal congenital and apical postgenital fusion of the carpels, first time reported in the genus, were observed in the gynoecium. Ovules are basally attached and crassinucellate; they appear to be slightly anatropous. The morphology of the filaments suggests a division of the species into two groups: Rhapis excelsa and R. subtilis exhibit thick and keeled filaments, whereas R. gracilis, R. humilis, R. laosensis, R. micrantha and R. multifida have slender, non-keeled filaments. Relationships of Rhapis with the rest of the genera of Rhapidinae are inferred on the light of floral structure.     

A revision of asterogyne (Arecaceae: Arecoideae: Geonomeae)

A taxonomic revision of the neotropical genusAsterogyne Hook. (Arecaceae: Arecoideae: Geonomeae) is presented. The genus is characterized by one autoapomorphic character, the separation of anther thecae by a bifid connective, and the combination of small to medium-sized stems, bifid simple leaf blades, floral pits in bud covered by a rounded upper lip that overlaps a lower lip, and pistillate flowers with staminodial lobes that are displayed in a starlike shape. Five species are recognized in this treatment: one of them (Asterogyne martiana) is widely distributed from Belize in Central America to northern Ecuador, three species (A. ramosa, A. spicata, andA. yaracuyense) are endemic to small areas in the Venezuelan Coastal Range, and one species (A. guianensis) is endemic to eastern French Guiana. The taxonomic history, morphology, reproductive biology, distribution and ecology, intrageneric relationships, and conservation status are reviewed.     

The social context for harvestingIriartea deltoidea (Arecaceae)

Iriartea deltoidea grows abundantly from Nicaragua to Bolivia. The stem is harvested for construction, furniture making, and handicrafts. The objective of my study was to understand the potential for sustainable harvesting of this palm. Ethnographic fieldwork about market patterns and decision-making among harvesters revealed the nature of harvesting pressures near settled areas. The study also demonstrates methods for assessing social and economic influences on harvesting.