The charophycean green algae provide insights into the early origins of plant cell walls.

Numerous evolutionary innovations were required to enable freshwater green algae to colonize terrestrial habitats and thereby initiate the evolution of land plants (embryophytes). These adaptations probably included changes in cell-wall composition and architecture that were to become essential for embryophyte development and radiation. However, it is not known to what extent the polymers that are characteristic of embryophyte cell walls, including pectins, hemicelluloses, glycoproteins and lignin, evolved in response to the demands of the terrestrial environment or whether they pre-existed in their algal ancestors. Here we show that members of the advanced charophycean green algae (CGA), including the Charales, Coleochaetales and Zygnematales, but not basal CGA (Klebsormidiales and Chlorokybales), have cell walls that are comparable in several respects to the primary walls of embryophytes. Moreover, we provide both chemical and immunocytochemical evidence that selected Coleochaete species have cell walls that contain small amounts of lignin or lignin-like polymers derived from radical coupling of hydroxycinnamyl alcohols. Thus, the ability to synthesize many of the components that characterize extant embryophyte walls evolved during divergence within CGA. Our study provides new insight into the evolutionary window during which the structurally complex walls of embryophytes originated, and the significance of the advanced CGA during these events.

[1]  G. Wasteneys,et al.  Cortical microtubules optimize cell-wall crystallinity to drive unidirectional growth in Arabidopsis. , 2011, The Plant journal : for cell and molecular biology.

[2]  B. Kloareg,et al.  Evolution and diversity of plant cell walls: from algae to flowering plants. , 2011, Annual review of plant biology.

[3]  S. Persson,et al.  Cellulose synthases and synthesis in Arabidopsis. , 2011, Molecular plant.

[4]  M. Vincentz,et al.  Evolution of xyloglucan-related genes in green plants , 2010, BMC Evolutionary Biology.

[5]  J. Weng,et al.  The origin and evolution of lignin biosynthesis. , 2010, The New phytologist.

[6]  W. Willats,et al.  How Have Plant Cell Walls Evolved?1 , 2010, Plant Physiology.

[7]  Z. Popper,et al.  Beyond the Green: Understanding the Evolutionary Puzzle of Plant and Algal Cell Walls1 , 2010, Plant Physiology.

[8]  W. Willats,et al.  The distribution of cell wall polymers during antheridium development and spermatogenesis in the Charophycean green alga, Chara corallina. , 2009, Annals of botany.

[9]  Debra Mohnen,et al.  The structure, function, and biosynthesis of plant cell wall pectic polysaccharides. , 2009, Carbohydrate research.

[10]  M. Auer,et al.  Plant cell walls throughout evolution: towards a molecular understanding of their design principles. , 2009, Journal of experimental botany.

[11]  P. Harris,et al.  Xyloglucans of monocotyledons have diverse structures. , 2009, Molecular plant.

[12]  R. Burton,et al.  (1,3;1,4)-beta-D-glucans in cell walls of the poaceae, lower plants, and fungi: a tale of two linkages. , 2009, Molecular plant.

[13]  Sarah N. Kiemle,et al.  CELL‐WALL DEVELOPMENT AND BIPOLAR GROWTH IN THE DESMID PENIUM MARGARITACEUM (ZYGNEMATOPHYCEAE, STREPTOPHYTA). ASYMMETRY IN A SYMMETRIC WORLD 1 , 2009, Journal of phycology.

[14]  B. Marin,et al.  Streptophyte algae and the origin of embryophytes. , 2009, Annals of botany.

[15]  Andrew R. Robinson,et al.  Rapid analysis of poplar lignin monomer composition by a streamlined thioacidolysis procedure and near-infrared reflectance-based prediction modeling. , 2009, The Plant journal : for cell and molecular biology.

[16]  Mark W. Denny,et al.  Discovery of Lignin in Seaweed Reveals Convergent Evolution of Cell-Wall Architecture , 2009, Current Biology.

[17]  A. Darvill,et al.  Moss and liverwort xyloglucans contain galacturonic acid and are structurally distinct from the xyloglucans synthesized by hornworts and vascular plants. , 2008, Glycobiology.

[18]  A. Driouich,et al.  OCCURRENCE AND CHARACTERIZATION OF ARABINOGALACTAN‐LIKE PROTEINS AND HEMICELLULOSES IN MICRASTERIAS (STREPTOPHYTA) 1 , 2008, Journal of phycology.

[19]  Takahisa Hayashi,et al.  Presence of xyloglucan‐like polysaccharide in Spirogyra and possible involvement in cell–cell attachment , 2008 .

[20]  L. Franková,et al.  Mixed-linkage beta-glucan : xyloglucan endotransglucosylase, a novel wall-remodelling enzyme from Equisetum (horsetails) and charophytic algae. , 2008, The Plant journal : for cell and molecular biology.

[21]  S. Fry,et al.  Mixed-linkage (1-->3,1-->4)-beta-D-glucan is a major hemicellulose of Equisetum (horsetail) cell walls. , 2008, The New phytologist.

[22]  Z. Popper Evolution and diversity of green plant cell walls. , 2008, Current opinion in plant biology.

[23]  W. Willats,et al.  Pectic homogalacturonan masks abundant sets of xyloglucan epitopes in plant cell walls , 2008, BMC Plant Biology.

[24]  Monika S. Doblin,et al.  Mixed-linkage (1-->3),(1-->4)-beta-D-glucan is not unique to the Poales and is an abundant component of Equisetum arvense cell walls. , 2008, The Plant journal : for cell and molecular biology.

[25]  K. Ruel,et al.  Immunocytochemical detection of lignin-related epitopes in cell walls in bryophytes and the charalean alga Nitella , 2008, Plant Systematics and Evolution.

[26]  Antony Bacic,et al.  High-throughput mapping of cell-wall polymers within and between plants using novel microarrays. , 2007, The Plant journal : for cell and molecular biology.

[27]  J. Boyer,et al.  Periplasm turgor pressure controls wall deposition and assembly in growing Chara corallina cells. , 2006, Annals of botany.

[28]  D. Cosgrove Growth of the plant cell wall , 2005, Nature Reviews Molecular Cell Biology.

[29]  J. Boyer,et al.  Turgor pressure moves polysaccharides into growing cell walls of Chara corallina. , 2005, Annals of botany.

[30]  C. Delwiche,et al.  Charophyte algae and land plant origins. , 2004, Trends in ecology & evolution.

[31]  R. McCourt,et al.  Green algae and the origin of land plants. , 2004, American journal of botany.

[32]  K. Niklas,et al.  The Cell Walls that Bind the Tree of Life , 2004 .

[33]  S. Fry Primary cell wall metabolism: tracking the careers of wall polymers in living plant cells. , 2004, The New phytologist.

[34]  E. Waters,et al.  Molecular adaptation and the origin of land plants. , 2003, Molecular phylogenetics and evolution.

[35]  G. Wasteneys,et al.  Cellulose microfibril alignment recovers from DCB-induced disruption despite microtubule disorganization. , 2003, The Plant journal : for cell and molecular biology.

[36]  G. Wasteneys,et al.  Mutation or Drug-Dependent Microtubule Disruption Causes Radial Swelling without Altering Parallel Cellulose Microfibril Deposition in Arabidopsis Root Cells Online version contains Web-only data. Article, publication date, and citation information can be found at www.plantcell.org/cgi/doi/10.1105/t , 2003, The Plant Cell Online.

[37]  Charles F. Delwiche,et al.  The Closest Living Relatives of Land Plants , 2001, Science.

[38]  B. Ridley,et al.  Pectins: structure, biosynthesis, and oligogalacturonide-related signaling. , 2001, Phytochemistry.

[39]  U. Lütz-Meindl,et al.  Cell wall secretion in the green alga Micrasterias , 2000, Journal of microscopy.

[40]  L. Graham,et al.  The origin of plants: body plan changes contributing to a major evolutionary radiation. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[41]  M. Melkonian,et al.  THE CELL WALL (THECA) OF TETRASELMIS STRIATA (CHLOROPHYTA): MACROMOLECULAR COMPOSITION AND STRUCTURAL ELEMENTS OF THE COMPLEX POLYSACCHARIDES , 1998 .

[42]  Peter R. Crane,et al.  The origin and early evolution of plants on land , 1997, Nature.

[43]  C. Lapierre,et al.  The phenolic domain of potato suberin: Structural comparison with lignins , 1996 .

[44]  A. Bacic,et al.  Extracellular polysaccharides from suspension cultures of Nicotiana plumbaginifolia , 1995 .

[45]  M. Melkonian,et al.  Structure, composition, and biogenesis of prasinophyte cell coverings , 1994, Protoplasma.

[46]  Hahn,et al.  Generation of Monoclonal Antibodies against Plant Cell-Wall Polysaccharides (I. Characterization of a Monoclonal Antibody to a Terminal [alpha]-(1->2)-Linked Fucosyl-Containing Epitope , 1994, Plant physiology.

[47]  D. Domozych,et al.  Scale biogenesis in the green alga,Mesostigma viride , 1992, Protoplasma.

[48]  N. Carpita,et al.  Changes in Esterification of the Uronic Acid Groups of Cell Wall Polysaccharides during Elongation of Maize Coleoptiles. , 1992, Plant physiology.

[49]  D. Domozych,et al.  Basket scales of the green alga, Mesostigma viride : chemistry and ultrastructure , 1991 .

[50]  M. Gretz,et al.  THE COMPOSITION AND PHYLOGENETIC SIGNIFICANCE OF THE MOUGEOTIA (CHAROPHYCEAE) CELL WALL 1 , 1989 .

[51]  C. Delwiche,et al.  Lignin-Like Compounds and Sporopollenin Coleochaete, an Algal Model for Land Plant Ancestry , 1989, Science.

[52]  P. Albersheim,et al.  3-deoxy-d-manno-2-octulosonic acid (KDO) is a component of rhamnogalacturonan II, a pectic polysaccharide in the primary cell walls of plants , 1985 .

[53]  Ionel Ciucanu,et al.  A simple and rapid method for the permethylation of carbohydrates , 1984 .

[54]  L. Graham Coleochaete and the origin of land plants , 1984 .

[55]  D. Updegraff Semimicro determination of cellulose in biological materials. , 1969, Analytical biochemistry.

[56]  P. Sandford,et al.  The structure of the Aerobacter aerogenes A3(S1) polysaccharide. I. A reexamination using improved procedures for methylation analysis. , 1966, Biochemistry.

[57]  N. J. King,et al.  Polysaccharides of the Characeae. II. The carbohydrate content of Nitella translucens. , 1961, Biochimica et biophysica acta.

[58]  N. J. King,et al.  Polysaccharides of the Characeae. III. The carbohydrate content of Chara australis. , 1961, Biochimica et biophysica acta.

[59]  K. Niklas,et al.  The evolution of the land plant life cycle. , 2010, The New phytologist.

[60]  P. Harris,et al.  Structural diversity, functions and biosynthesis of xyloglucans in angiosperm cell walls. , 2009 .

[61]  H. Tenhu,et al.  Comparison of the solution properties of (1→3),(1→4)-β-d-glucans extracted from oats and barley , 2008 .

[62]  Y. Guisez,et al.  XET activity is found near sites of growth and cell elongation in bryophytes and some green algae: new insights into the evolution of primary cell wall elongation. , 2007, Annals of botany.

[63]  A. Roberts,et al.  Evolution of the Cellulose Synthase (CesA) Gene Family: Insights from Green Algae and Seedless Plants , 2007 .

[64]  Sarah N. Kiemle,et al.  The structure and biochemistry of charophycean cell walls: I. Pectins of Penium margaritaceum , 2006, Protoplasma.

[65]  R. Henry,et al.  Diversity in plant cell walls. , 2005 .

[66]  Zoë A Popper,et al.  Primary cell wall composition of bryophytes and charophytes. , 2003, Annals of botany.

[67]  N. Carpita,et al.  Structural models of primary cell walls in flowering plants: consistency of molecular structure with the physical properties of the walls during growth. , 1993, The Plant journal : for cell and molecular biology.

[68]  L. Graham Origin of land plants , 1993 .

[69]  Antony Bacic,et al.  8 – Structure and Function of Plant Cell Walls , 1988 .

[70]  C. Lapierre,et al.  Thioacidolysis of Poplar Lignins: Identification of Monomeric Syringyl Products and Characterization of Guaiacyl-Syringyl Lignin Fractions , 1986 .

[71]  N. J. King,et al.  1052. Polysaccharides of the characeae. Part IV. A non-esterified pectic acid from Nitella translucens , 1961 .