Arabinogalactan protein

(Redirected from Arabinogalactan proteins)

Arabinogalactan-proteins (AGPs) are highly glycosylated proteins (glycoproteins) found in the cell walls of plants. Each one consists of a protein with sugar molecules attached (which can account for more than 90% of the total mass). They are members of the wider class of hydroxyproline (Hyp)-rich cell wall glycoproteins, a large and diverse group of glycosylated wall proteins.

AGPs have been reported in a wide range of higher plants in seeds, roots, stems, leaves and inflorescences. AGPs account for only a small portion of the cell wall, usually no more than 1% of dry mass of the primary wall. They have also been reported in secretions of cell culture medium of root, leaf, endosperm and embryo tissues, and some exudate producing cell types such as stylar canal cells are capable of producing lavish amounts of AGPs. They are implicated in various aspects of plant growth and development, including root elongation, somatic embryogenesis, hormone responses, xylem differentiation, pollen tube growth and guidance, programmed cell death, cell expansion, salt tolerance, host-pathogen interactions, and cellular signaling.

AGPs have attracted considerable attention due to their highly complex structures and potential roles in signalling. In addition, they have industrial and health applications due to their chemical/physical properties (water-holding, adhesion and emulsification).

Sequence and classification

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Protein sequence of a classical, GPI-anchored AGP from Arabidopsis thaliana (AtAGP3). Features directing post-translational modification are highlighted: ER signal sequence highlighted purple, AGP glycomotifs highlighted blue and GPI signal sequence boxed.

The protein component of AGPs is rich in the amino acids Proline (P), Alanine (A), Serine (S) and Threonine (T), also known as ‘PAST’, and this amino acid bias is one of the features used to identify them.[1][2][3][4] AGPs are intrinsically disordered proteins as they contain a high proportion of disordering amino acids such as Proline that disrupt the formation of stable folded structures. Characteristic of intrinsically disordered proteins, AGPs also contain repeat motifs and post-translational modifications.[2][5] Proline residues in the protein backbone can be hydroxylated to Hydroxyproline (O) depending on the surrounding amino acids. The ‘Hyp contiguity hypothesis’ [6][2][3] predicts that when O occurs in a non-contiguous manner, for example the sequence 'SOTO', such as occurs in AGPs, this acts as a signal for O-linked glycosylation of large branched type II arabinogalactan (AG) polysaccharides.[7] Sequences that direct AG glycosylation (SO, TO, AO, VO) are called AGP glycomotifs.

All AGP protein backbones contain a minimum of 3 clustered AGP glycomotifs and an N-terminal signal peptide that directs the protein into the endoplasmic reticulum (ER) where post-translational modifications begin.[8] Prolyl hydroxylation of P to O is fulfilled by prolyl 4-hydroxylases (P4Hs) belonging to the 2-oxoglutarate dependant dioxygenase family.[9] P4H has been identified in both the ER and Golgi apparatus.[10] The addition of the glycosylphosphatidylinositol (GPI)-anchor occurs in most but not all AGPs.[3][4]

Families

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Schematic of the predicted structures of selected AGP sub-families. Classical AGPs contain glycomotifs directing hydroxylation of P to O and subsequent O-glycosylation to which large type II arabinogalactan chains (Type II AG, yellow shapes) are attached. Many AGPs are predicted to contain a GPI-anchor at the C-terminus. Hybrid AGPs contain motifs characteristic of more than one HRGP family, for example glycomotifs typical of extensins (SP3-5; red bars) that direct addition of short arabinose (Ara) side chains (dark red) on Hyp and galactose (Gal; green) on Ser residues. Cross-linking Tyr motifs (dark blue bars) may also be present in the protein backbone. Chimeric AGPs have a recognised PFAM domain (green) in addition to the AGP region.

AGPs belong to large multigene families and are divided into several sub-groups depending on the predicted protein sequence.[11][4][12][13][2][14] "Classical" AGPs include the GPI-AGPs that consist of a signal peptide at the N-terminus, a PAST-rich sequence of 100-150 aa and a hydrophobic region at the C-terminus that directs addition of a GPI-anchor; non GPI-AGPs that lack the C-terminal GPI signal sequence, Lysine(K)-rich AGPs that contain a K-rich region within the PAST-rich backbone and AG-peptide that have a short PAST-rich backbone of 10-15 aa (Figure 2). Chimeric AGPs consist of proteins that have an AGP region and an additional region with a recognised protein family (Pfam) domain. Chimeric AGPs include fasciclin-like AGPs (FLAs), phytocyanin-like AGPs (PAGs/PLAs, also known as early-nodulin-like proteins, ENODLs) and xylogen-like AGPs (XYLPs) that contain lipid-transfer-like domains.[1] Several other putative chimeric AGP classes have been identified that include AG glycomotifs associated with protein kinase, leucine-rich repeat, X8, FH2 and other protein family domains.[2][15][16] Other non-classical AGPs exist such as those containing a cysteine(C)-rich domain, also called PAC domains, and/or histidine(H)-rich domain,[17][18] as well as many hybrid HRGPs that have motifs characteristic of AGPs and other HRGP members, usually extensin and Tyr motifs.[17][19][1][2][14] AGPs are evolutionarily ancient and have been identified in green algae as well as Chromista and Glaucophyta.[2][14][20] Found throughout the entire plant lineage, land plants are suggested to have inherited and diversified the existing AGP protein backbone genes present in algae to generate an enormous number of AGP glycoforms.

Structure

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The carbohydrate moieties of AGPs are rich in arabinose and galactan, but other sugars may also be found such as L-rhamnopyranose (L-Rhap), D-mannopyranose (Manp), D-xylopyranose (Xylp), L-fucose (Fuc), D-glucopyranose (Glcp), D-glucuronic acid (GlcA) and its 4-O-methyl derivative, and D-galacturonic acid (GalA) and its 4-O-methyl derivative.[21][22] The AG found in AGPs is of type II (type II AGs) – that is, a galactan backbone of (1-3)-linked β-D-galactopyranose (Galp) residues, with branches (between one and three residues long) of (1,6)-linked β-D-Galp. In most cases, the Gal residues terminate with α-L-arabinofuranose (Araf) residues. Some AGPs are rich in uronic acids (GlcA), resulting in a charged polysaccharide moiety, and others have short oligosaccharides of Araf.[23] Specific sets of hydroxyproline O-β-galactosyltransferases, β-1,3-galactosyltransferases, β-1,6-galactosyltransferases, α-arabinosyltransferases, β-glucuronosyltransferases, α-rhamnosyltransferases, and α- fucosyltransferases are responsible for the synthesis of these complex structures.[24]

One of the features of type II AGs, particularly the (1,3)-linked β-D-Galp residues, is their ability to bind to the Yariv phenylglycosides. Yariv phenylglycosides are widely used as cytochemical reagents to perturb the molecular functions of AGPs as well as for the detection, quantification, purification, and staining of AGPs.[21] Recently, it was reported that interaction with Yariv was not detected for β-1,6-galacto-oligosaccharides of any length.[25] Yariv phenylglycosides were concluded to be specific binding reagents for β-1,3-galactan chains longer than five residues. Seven residues and longer are sufficient for cross-linking, leading to precipitation of the glycans with the Yariv phenylglycosides, which are observed with classical AGPs binding to β-Yariv dyes. The same results were observed where in AGPs appear to need at least 5–7 β-1,3-linked Gal units to make aggregates with the Yariv reagent.[26]

Biosynthesis

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After translation, the AGP protein backbones are highly decorated with complex carbohydrates, primarily type II AG polysaccharides.[27] The biosynthesis of the mature AGP involves cleavage of the signal peptide at the N-terminus, hydroxylation on the P residues and subsequent glycosylation and in many cases addition of a GPI-anchor.

Processing and transport

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Glycosylation of the AGP backbone is suggested to initiate in the ER with the addition of first Gal by O-galactosyltransferase, which is predominantly located in ER fractions.[28] Chain extension then occurs primarily in the GA.[29] For those AGPs that include a GPI anchor, addition occurs while co-translationally migrating into the ER.

Arabinogalactan sidechains

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The structure of the AG glycans consists of a backbone of β-1,3 linked galactose (Gal), with sidechains of β-1,6 linked Gal and have terminal residues of arabinose (Ara), rhamnose (Rha), Gal, fucose (Fuc), and glucuronic acid (GlcA). These AG glycan moieties are assembled by glycosyltransferases (GTs).[30] O-glycosylation of AGPs is initiated by the action of Hyp-O-galactosyltransferases (Hyp-O-GalTs) that add the first Gal onto the protein. The complex glycan structures are then elaborated by a suite of glycosyltransferases, the majority of which are bio-chemically uncharacterized. The GT31 family is one of the families involved in AGP glycan backbone biosynthesis.[31][32] Numerous members of the GT31 family have been identified with Hyp-O-GALT activity[33][34] and the core β-(1,3)-galactan backbone is also likely to be synthesized by the GT31 family.[32] Members of the GT14 family are implicated in adding β-(1,6)- and β-(1,3)-galactans to AGPs.[35][36] In Arabidopsis, terminal sugars such as fucose are proposed to be added by AtFUT4 (a fucosyl transferase) and AtFUT6 in the GT37 family [37][38] and the terminal GlcA incorporation can be catalysed by the GT14 family.[35][39] A number of GTs remain to be identified, for example those responsible for terminal Rha.

GPI-anchor

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Bioinformatic analysis predicts the addition of a GPI-anchor on many AGPs.[4] The early synthesis of the GPI moiety occurs on the ER cytoplasmic surface and subsequent assembly take place in the lumen of the ER. These include the assembly of tri-mannose (Man), galactose, non-N-acetylated glucosamine (GlcN) and ethanolamine phosphate to form the mature GPI moiety.[40][41] AGPs undergo GPI-anchor addition while co-translationally migrating into the ER and these two processes finally converge. Subsequently, a transamidase complex simultaneously cleaves the core protein at the C-terminus when it recognizes the ω cleavage site and transfers the fully assembled GPI-anchor onto the amino acid residue at the C-terminus of the protein. These events occur prior to prolyl hydroxylation and glycosylation.[42][10] The core glycan structure of GPI anchors is Man-α-1,2-Man-α-1,6-Man-α-1,4-GlcN-inositol (Man: mannose, GlcN: glucosaminyl), which is conserved in many eukaryotes.[41][43][44][40][10][45] The only plant GPI anchor structure characterized to date is the GPI-anchored AGP from Pyrus communis suspension-cultured cells.[40] This showed a partially modified glycan moiety compared to previously characterized GPI anchors as it contained β-1,4-Gal. The GPI anchor synthesis and protein assembly pathway is proposed to be conserved in mammals and plants.[10] The integration of a GPI-anchor enables the attachment of the protein to the membrane of the ER transiting to the GA leading to secretion to the outer leaflet of the plasma membrane facing the wall.[46] As proposed by Oxley and Bacic,[40] the GPI-anchored AGPs are likely released via cleavage by some phospholipases (PLs) (C or D) and secreted into the extracellular compartment.

Functionally characterized genes involved in AGP glycosylation

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Bioinformatics analysis using mammalian β-1,3-galactosyltransferase (GalT) sequences as templates suggested involvement of the Carbohydrate-Active enZYmes (CAZy) glycosyltransferase (GT) 31 family in the synthesis of the galactan chains of the AG backbone.[47] Members of the GT31 family have been grouped into 11 clades, with four clades being plant-specific: Clades 1, 7, 10, and 11. Clades 1 and 11 domains and motifs are not well-defined; while Clades 7 and 10 have domain similarities with proteins of known GalT function in mammalian systems.[47] Clade 7 proteins contain both GalT and galectin domains, while Clade 10 proteins contain a GalT-specific domain.[48] The galectin domain is proposed to allow the GalT to bind to the first Gal residue on the polypeptide backbone of AGPs; thus, determining the position of subsequent Gal residues on the protein backbone, similar to the activity of human galectin domain-containing proteins.[47]

Eight enzymes belonging to the GT31 family demonstrated the ability to place the first Gal residue onto Hyp residues in AGP core proteins. These enzymes are named GALT2, GALT3, GALT4, GALT5, GALT6,[49] which are Clade 7 members, and HPGT1, HPGT2, and HPGT3,[50] which are Clade 10 members. Preliminary enzyme substrate specificity studies demonstrated that another GT31 Clade 10 enzyme, At1g77810, had β-1,3-GalT activity.[47] A GT31 Clade 10 gene, KNS4/UPEX1, encodes a β-1,3-GalT capable of synthesizing β-1,3-Gal linkages found in type II AGs present in AGPs and/or pectic rhamnogalacturonan I (RG-I).[51] Another GT31 Clade 10 member, named GALT31A, encodes a β-1,6-GalT when heterologously expressed in E. coli and Nicotiana benthamiana and elongated β-1,6-galactan side chains of AGP glycans.[52] GALT29A, a member of GT29 family was identified as being co-expressed with GALT31A and act co-operatively and form complexes.[53]

Three members of GT14 named GlcAT14A, GlcAT14B, and GlcAT14C were reported to add GlcA to both β-1,6- and β-1,3-Gal chains in an in vitro enzyme assay following heterologous expression in Pichia pastoris.[54] Two α-fucosyltransferase genes, FUT4 and FUT6, both belonging to GT37 family, encode enzymes which add α-1,2-fucose residues to AGPs.[55][56] They appear to be partially redundant as they display somewhat different AGP substrate specificities.[55] A GT77 family member, REDUCED ARABINOSE YARIV (RAY1), was found to be a β-arabinosyltransferase that adds a β-Araf to methyl β-Gal of a Yariv-precipitable wall polymer.[57] More research is expected to functionally identify other genes involved in AGP glycosylation and their interactions with other plant cell wall components.

Biological roles

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Human uses of AGPs include the use of gum arabic in the food and pharmaceutical industries because of natural properties in thickening and emulsification.[58][59] AGPs in cereal grains have potential applications in biofortification,[60] as sources of dietary fibre to support gut bacteria[61] and protective agents against ethanol toxicity.[62]

AGPs are found in a wide range of plant tissues, in secretions of cell culture medium of root, leaf, endosperm and embryo tissues, and some exudate producing cell types such as stylar canal cells.[19][63] AGPs have been shown to regulate many aspects of plant growth and development including male-female recognition in reproduction organs, cell division and differentiation in embryo and post-embryo development, seed mucilage cell wall development, root salt tolerance and root-microbe interactions.[64][10][65] These studies suggest that they are multifunctional, similar to what is found in mammalian proteoglycans/glycoproteins.[66][67][68] Conventional methods to study functions of AGPs include the use of β-glycosyl (usually glucosyl) Yariv reagents and monoclonal antibodies (mAbs). β-Glycosyl Yariv reagents are synthetic phenylazo glycoside probes that specifically, but not covalently, bind to AGPs and can be used to precipitate AGPs from solution.[69] They are also used commonly as histochemical stains to probe the locations and distribution of AGPs.[70][71] A number of studies have shown that addition of β-Yariv reagents to plant growth medium can inhibit seedling growth, cell elongation, block somatic embryogenesis and fresh cell wall mass accumulation.[72][73][74] The use of mAbs that specifically bind to carbohydrate epitopes of AGPs have also been employed to infer functions based on the location and pattern of the AGP epitopes.[75] Commonly used mAb against AGPs include CCRC-M7, LM2, JIM8, JIM13 and JIM14.[76]

The function of individual AGPs has largely been inferred through studies of mutants. For example, the Arabidopsis root-specific AtAGP30 was shown to be required for in vitro root regeneration suggesting a function in regenerating the root by modulating phytohormone activity.[77] Studies of agp6 and agp11 mutants in Arabidopsis have demonstrated the importance of these AGPs to prevent uncontrolled generation of the pollen grain and for normal growth of the pollen tube.[78][79] The functional mechanisms of AGPs in cell signalling is not well understood. One proposed model suggests AGPs can interact and control the release of calcium from AG glycan (via GlcA residues) to trigger downstream signalling pathways mediated by calcium.[80][81][82] Another possible mechanism, largely based on the study of FLAs, suggests the combination of fasciclin domain and AG glycans can mediate cell-cell adhesion.[83][84]

Proposed functions of AGPs in plant growth and development
Biological role AGP [a][b] Location(s) Function(s) References
Embryogenesis GhPLA1 Somatic embryos Promoting somatic embryogenesis [85]
DcAGPs Somatic embryos Promoting somatic embryogenesis [86]
AtAGPs Embryos Embryo development and differentiation [87]
NtAGPs Embryos Embryo development [88]
BgAGPs Somatic embryos Somatic embryo development rate and morphology [89]
BnAGPs Embryos Embryo development [21]
MaAGPs Somatic embryos Promoting somatic embryogenesis [90]
PsAGPs Promoting somatic embryogenesis [91]
FsAGPs Embryos Establishment and stability of the cell wall [20]
VcALGAL-CAM embryos Embryo cell adhesion [83]
VcISG embryos Embryo inversion [92]
Reproduction AtAGP4 (JAGGER) Pistil Pollen tube blockage [93]
AtAGP6, AtAGP11 Stamen, pollen grain and pollen tube Pollen grain development and pollen tube growth [94][95]
AtAGP18 Ovule Megaspore selection [96][97]
AtFLA3 Pollen grain and pollen tube Microspore development [98]
AtENODL11-15 Micropylar Pollen tube reception [99][100]
BcmMF8 Pollen grain and pollen tube Pollen wall development and pollen tube growth [101]
BcmMF18 Pollen grain Pollen grain development, intine formation [102]
NtTTS Pistil Pollen tube growth and guidance [103]
Np/Na120kD Pistil S-specific pollen rejection (self-incompatibility) [104]
OsMTR1 Male reproductive cells Anther development and pollen fertility [105]
Plant development AtAGP19 Stem, flower, root and leaf Cell division and expansion, leaf development and reproduction [106]
AtAGP57C Rosette leaf, silique, seed, flower, and shoot apex of inflorescence stem Cell wall structure maintenance [107]
AtFLA1 Stomata, trichome, leaf vasculature, primary root tip and lateral root Lateral root development and shoot regeneration [108]
AtFLA4 (SOS5) Flower, leaf, stem, root, silique Root salt stress tolerance; seed mucilage adherence [109][110][111][112][113]
PpAGP1 Apical cells Apical cell expansion [114]
AtAGP30 Root Root regeneration and seed germination [47]
BcrFLA1 Root Root hair elongation [115]
Secondary wall development AtFLA11, AtFLA12 Stem and branch Secondary cell wall synthesis/patterning [116]
AtXYP1, AtXYP2 Cell walls of differentiating tracheary elements Vascular tissue development and patterning [117]
GhAGP4 Cotton fiber Cotton fiber initiation and elongation [98]
GhFLA1 Cotton fiber Fiber initiation and elongation [52]
PtFLA6 Stem xylem fiber Secondary cell wall synthesis/patterning [118]
Defense SlattAGP Site of parasite attack Promotes parasite adherence [119]
Plant-microbe interaction AtAGP17 Root Agrobacterium tumefaciens root transformation [120]
  1. ^ Gh: Gossypium hirsutum, Dc: Daucus carota, At: Arabidopsis thaliana, Nt: Nicotiana tabacum, Bg: Bactris gasipaes, Bn: Brassica napus, Ma: Musa spp. AAA, Ps: Pelargonium sidoides, Fs: Fucus serratus, Vc: Volvox carteri, Bcm: Brassica campestris, Np: Nicotiana plumbaginifolia, Na: Nicotiana alata, Os: Oryza sativa, Pp: Physcomitrella patens, Bcr: Brassica carinata, Pt: Populus trichocarpa, Sl: Solanum lycopersicum.
  2. ^ PLA: phytocyanin-like AGP. ALGAL-CAM: algal cell adhesion molecule. ISG: inversion-specific glycoprotein. FLA: fasciclin like AGP. ENODL: earlt nodulation like. MF: male fertility. TTS: transmitting tissue specific. MTR: microspore and tapetum regulator. SOS: salt overly sensitive. XYP: xylogen protein. attAGP: attachment AGP.

The functions of AGPs in plant growth and development processes rely heavily on the incredible diversity of their glycan and protein backbone moieties.[121] In particular, it is the AG polysaccharides that are most likely to be involved in development.[122] Most of the biological roles of AGPs have been identified through T-DNA insertional mutants characterization of genes or enzymes involved in AGP glycosylation, primarily in Arabidopsis thaliana. The galt2-6 single mutants revealed some physiological phenotypes under normal growth conditions, including reduced root hair length and density, reduced seed set, reduced adherent seed coat mucilage, and premature senescence.[123] However, galt2galt5 double mutants showed more severe and pleiotropic physiological phenotypes than the single mutants with respect to root hair length and density and seed coat mucilage.[123] Similarly, hpgt1hpgt2hpgt3 triple mutants showed several pleiotropic phenotypes including longer lateral roots, increased root hair length and density, thicker roots, smaller rosette leaves, shorter petioles, shorter inflorescence stems, reduced fertility, and shorter siliques.[50] In the case of GALT31A, it has been found to be essential for embryo development in Arabidopsis. A T-DNA insertion in the 9th exon of GALT31A resulted in embryo lethality of this mutant line.[52] Meanwhile, knockout mutants for KNS4/UPEX1 have collapsed pollen grains and abnormal pollen exine structure and morphology.[124] In addition, kns4 single mutants exhibited reduced fertility, confirming that KNS4/UPEX1 is critical for pollen viability and development.[51] Knockout mutants for FUT4 and FUT6 showed severe inhibition in root growth under salt conditions[56] while knockout mutants for GlcAT14A, GlcAT14B, and GlcAT14C showed enhanced cell elongation rates in dark grown hypocotyls and light grown roots during seedling growth.[125] In the case of ray1 mutant seedlings grown on vertical plates, the length of the primary root was affected by RAY1 mutation. In addition, the primary root of ray1 mutants grew with a slower rate compared to wild-type Arabidopsis.[57] Taken together, these studies provide evidence that proper glycosylation of AGPs is important to AGP function in plant growth and development.

Human uses

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Human uses of AGPs include the use of Gum arabic in the food and pharmaceutical industries because of natural properties in thickening and emulsification.[58][59] AGPs in cereal grains have potential applications in biofortification,[60] as sources of dietary fibre to support gut bacteria[61] and protective agents against ethanol toxicity.[62]

See also

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References

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  This article was adapted from the following source under a CC BY 4.0 license (2021) (reviewer reports): Yingxuan Ma; Kim Johnson (15 January 2021). "Arabinogalactan-proteins" (PDF). WikiJournal of Science. 4 (1): 2. doi:10.15347/WJS/2021.002. ISSN 2470-6345. Wikidata Q99557488.

  1. ^ a b c Showalter, Allan M.; Keppler, Brian; Lichtenberg, Jens; Gu, Dazhang; Welch, Lonnie R. (2010-04-15). "A Bioinformatics Approach to the Identification, Classification, and Analysis of Hydroxyproline-Rich Glycoproteins". Plant Physiology. 153 (2): 485–513. doi:10.1104/pp.110.156554. ISSN 0032-0889. PMC 2879790. PMID 20395450.
  2. ^ a b c d e f g Johnson, Kim L.; Cassin, Andrew M.; Lonsdale, Andrew; Bacic, Antony; Doblin, Monika S.; Schultz, Carolyn J. (2017-04-26). "Pipeline to Identify Hydroxyproline-Rich Glycoproteins". Plant Physiology. 174 (2): 886–903. doi:10.1104/pp.17.00294. ISSN 0032-0889. PMC 5462032. PMID 28446635.
  3. ^ a b c Johnson, Kim L.; Cassin, Andrew M.; Lonsdale, Andrew; Wong, Gane Ka-Shu; Soltis, Douglas E.; Miles, Nicholas W.; Melkonian, Michael; Melkonian, Barbara; Deyholos, Michael K. (2017-04-26). "Insights into the Evolution of Hydroxyproline-Rich Glycoproteins from 1000 Plant Transcriptomes". Plant Physiology. 174 (2): 904–921. doi:10.1104/pp.17.00295. ISSN 0032-0889. PMC 5462033. PMID 28446636.
  4. ^ a b c d Schultz, Carolyn J.; Rumsewicz, Michael P.; Johnson, Kim L.; Jones, Brian J.; Gaspar, Yolanda M.; Bacic, Antony (2002-08-01). "Using Genomic Resources to Guide Research Directions. The Arabinogalactan Protein Gene Family as a Test Case". Plant Physiology. 129 (4): 1448–1463. doi:10.1104/pp.003459. ISSN 0032-0889. PMC 166734. PMID 12177459.
  5. ^ Shafee, Thomas; Bacic, Antony; Johnson, Kim (2020-08-01). Wilke, Claus (ed.). "Evolution of Sequence-Diverse Disordered Regions in a Protein Family: Order within the Chaos". Molecular Biology and Evolution. 37 (8): 2155–2172. doi:10.1093/molbev/msaa096. ISSN 0737-4038. PMID 32359163.
  6. ^ Kieliszewski, Marcia J.; Lamport, Derek T.A. (February 1994). "Extensin: repetitive motifs, functional sites, post-translational codes, and phylogeny". The Plant Journal. 5 (2): 157–172. doi:10.1046/j.1365-313x.1994.05020157.x. ISSN 0960-7412. PMID 8148875.
  7. ^ Tan, Li; Leykam, Joseph F.; Kieliszewski, Marcia J. (2003-06-12). "Glycosylation Motifs That Direct Arabinogalactan Addition to Arabinogalactan-Proteins". Plant Physiology. 132 (3): 1362–1369. doi:10.1104/pp.103.021766. ISSN 0032-0889. PMC 167076. PMID 12857818.
  8. ^ Schultz, Carolyn; Gilson, Paul; Oxley, David; Youl, Joelian; Bacic, Antony (November 1998). "GPI-anchors on arabinogalactan-proteins: implications for signalling in plants". Trends in Plant Science. 3 (11): 426–431. doi:10.1016/s1360-1385(98)01328-4. ISSN 1360-1385.
  9. ^ Koski, M. Kristian; Hieta, Reija; Böllner, Claudia; Kivirikko, Kari I.; Myllyharju, Johanna; Wierenga, Rik K. (2007-12-21). "The active site of an algal prolyl 4-hydroxylase has a large structural plasticity". The Journal of Biological Chemistry. 282 (51): 37112–37123. doi:10.1074/jbc.M706554200. ISSN 0021-9258. PMID 17940281.
  10. ^ a b c d e Ellis, Miriam; Egelund, Jack; Schultz, Carolyn J.; Bacic, Antony (2010-04-13). "Arabinogalactan-Proteins: Key Regulators at the Cell Surface?". Plant Physiology. 153 (2): 403–419. doi:10.1104/pp.110.156000. ISSN 0032-0889. PMC 2879789. PMID 20388666.
  11. ^ Showalter, A. M. (September 2001). "Arabinogalactan-proteins: structure, expression and function". Cellular and Molecular Life Sciences. 58 (10): 1399–1417. doi:10.1007/pl00000784. ISSN 1420-682X. PMC 11337269. PMID 11693522. S2CID 206858189.
  12. ^ Gaspar, Yolanda Maria; Nam, Jaesung; Schultz, Carolyn Jane; Lee, Lan-Ying; Gilson, Paul R.; Gelvin, Stanton B.; Bacic, Antony (2004-07-30). "Characterization of the Arabidopsis Lysine-Rich Arabinogalactan-Protein AtAGP17 Mutant (rat1) That Results in a Decreased Efficiency of Agrobacterium Transformation". Plant Physiology. 135 (4): 2162–2171. doi:10.1104/pp.104.045542. ISSN 0032-0889. PMC 520787. PMID 15286287.
  13. ^ Huang, Geng-Qing; Gong, Si-Ying; Xu, Wen-Liang; Li, Wen; Li, Peng; Zhang, Chao-Jun; Li, Deng-Di; Zheng, Yong; Li, Fu-Guang (2013-01-24). "A Fasciclin-Like Arabinogalactan Protein, GhFLA1, Is Involved in Fiber Initiation and Elongation of Cotton". Plant Physiology. 161 (3): 1278–1290. doi:10.1104/pp.112.203760. ISSN 0032-0889. PMC 3585596. PMID 23349362.
  14. ^ a b c Johnson, Kim L.; Cassin, Andrew M.; Lonsdale, Andrew; Wong, Gane Ka-Shu; Soltis, Douglas E.; Miles, Nicholas W.; Melkonian, Michael; Melkonian, Barbara; Deyholos, Michael K. (2017-04-26). "Insights into the Evolution of Hydroxyproline-Rich Glycoproteins from 1000 Plant Transcriptomes". Plant Physiology. 174 (2): 904–921. doi:10.1104/pp.17.00295. ISSN 0032-0889. PMC 5462033. PMID 28446636.
  15. ^ Dragićević, Milan B; Paunović, Danijela M; Bogdanović, Milica D; Todorović, Sladjana I; Simonović, Ana D (2020-01-01). "ragp: Pipeline for mining of plant hydroxyproline-rich glycoproteins with implementation in R". Glycobiology. 30 (1): 19–35. doi:10.1093/glycob/cwz072. ISSN 1460-2423. PMID 31508799.
  16. ^ Pfeifer, Lukas; Shafee, Thomas; Johnson, Kim L.; Bacic, Antony; Classen, Birgit (December 2020). "Arabinogalactan-proteins of Zostera marina L. contain unique glycan structures and provide insight into adaption processes to saline environments". Scientific Reports. 10 (1): 8232. Bibcode:2020NatSR..10.8232P. doi:10.1038/s41598-020-65135-5. ISSN 2045-2322. PMC 7237498. PMID 32427862.
  17. ^ a b Baldwin, Timothy C.; Domingo, Concha; Schindler, Thomas; Seetharaman, Gouri; Stacey, Nicola; Roberts, Keith (2001). "DcAGP1, a secreted arabinogalactan protein, is related to a family of basic proline-rich proteins". Plant Molecular Biology. 45 (4): 421–435. doi:10.1023/A:1010637426934. hdl:2436/17032. PMID 11352461. S2CID 8322072.
  18. ^ Nguyen-Kim, Huan; San Clemente, Hélène; Laimer, Josef; Lackner, Peter; Gadermaier, Gabriele; Dunand, Christophe; Jamet, Elisabeth (2020-04-03). "The Cell Wall PAC (Proline-Rich, Arabinogalactan Proteins, Conserved Cysteines) Domain-Proteins Are Conserved in the Green Lineage". International Journal of Molecular Sciences. 21 (7): 2488. doi:10.3390/ijms21072488. ISSN 1422-0067. PMC 7177597. PMID 32260156.
  19. ^ a b Gaspar, Y.; Johnson, K. L.; McKenna, J. A.; Bacic, A.; Schultz, C. J. (September 2001). "The complex structures of arabinogalactan-proteins and the journey towards understanding function". Plant Molecular Biology. 47 (1–2): 161–176. doi:10.1023/A:1010683432529. ISSN 0167-4412. PMID 11554470. S2CID 19541545.
  20. ^ a b Hervé, Cécile; Siméon, Amandine; Jam, Murielle; Cassin, Andrew; Johnson, Kim L.; Salmeán, Armando A.; Willats, William G. T.; Doblin, Monika S.; Bacic, Antony (2015-12-15). "Arabinogalactan proteins have deep roots in eukaryotes: identification of genes and epitopes in brown algae and their role inFucus serratusembryo development". New Phytologist. 209 (4): 1428–1441. doi:10.1111/nph.13786. ISSN 0028-646X. PMID 26667994.
  21. ^ a b c Fincher, G. B.; Stone, B. A.; Clarke, A. E. (1983). "Arabinogalactan-Proteins: Structure, Biosynthesis, and Function". Annual Review of Plant Physiology. 34 (1): 47–70. doi:10.1146/annurev.pp.34.060183.000403.
  22. ^ Inaba, Miho; Maruyama, Takuma; Yoshimi, Yoshihisa; Kotake, Toshihisa; Matsuoka, Koji; Koyama, Tetsuo; Tryfona, Theodora; Dupree, Paul; Tsumuraya, Yoichi (2015-10-13). "l-Fucose-containing arabinogalactan-protein in radish leaves". Carbohydrate Research. 415: 1–11. doi:10.1016/j.carres.2015.07.002. ISSN 0008-6215. PMC 4610949. PMID 26267887.
  23. ^ Du, He; Clarke, Adrienne E.; Bacic, Antony (1996-11-01). "Arabinogalactan-proteins: a class of extracellular matrix proteoglycans involved in plant growth and development". Trends in Cell Biology. 6 (11): 411–414. doi:10.1016/S0962-8924(96)20036-4. ISSN 0962-8924. PMID 15157509.
  24. ^ Showalter, Allan M.; Basu, Debarati (2016). "Extensin and Arabinogalactan-Protein Biosynthesis: Glycosyltransferases, Research Challenges, and Biosensors". Frontiers in Plant Science. 7: 814. doi:10.3389/fpls.2016.00814. ISSN 1664-462X. PMC 4908140. PMID 27379116.
  25. ^ Kitazawa, Kiminari; Tryfona, Theodora; Yoshimi, Yoshihisa; Hayashi, Yoshihiro; Kawauchi, Susumu; Antonov, Liudmil; Tanaka, Hiroshi; Takahashi, Takashi; Kaneko, Satoshi (2013-03-01). "β-Galactosyl Yariv Reagent Binds to the β-1,3-Galactan of Arabinogalactan Proteins". Plant Physiology. 161 (3): 1117–1126. doi:10.1104/pp.112.211722. ISSN 0032-0889. PMC 3585584. PMID 23296690.
  26. ^ Paulsen, B. S.; Craik, D. J.; Dunstan, D. E.; Stone, B. A.; Bacic, A. (2014-06-15). "The Yariv reagent: Behaviour in different solvents and interaction with a gum arabic arabinogalactanprotein". Carbohydrate Polymers. 106: 460–468. doi:10.1016/j.carbpol.2014.01.009. ISSN 0144-8617. PMID 24721102.
  27. ^ Liang, Yan; Basu, Debarati; Pattathil, Sivakumar; Xu, Wen-liang; Venetos, Alexandra; Martin, Stanton L.; Faik, Ahmed; Hahn, Michael G.; Showalter, Allan M. (2013-10-14). "Biochemical and physiological characterization of fut4 and fut6 mutants defective in arabinogalactan-protein fucosylation in Arabidopsis". Journal of Experimental Botany. 64 (18): 5537–5551. doi:10.1093/jxb/ert321. ISSN 1460-2431. PMC 3871811. PMID 24127514.
  28. ^ Oka, Takuji; Saito, Fumie; Shimma, Yoh-ichi; Yoko-o, Takehiko; Nomura, Yoshiyuki; Matsuoka, Ken; Jigami, Yoshifumi (2009-11-18). "Characterization of Endoplasmic Reticulum-Localized UDP-d-Galactose: Hydroxyproline O-Galactosyltransferase Using Synthetic Peptide Substrates in Arabidopsis". Plant Physiology. 152 (1): 332–340. doi:10.1104/pp.109.146266. ISSN 0032-0889. PMC 2799367. PMID 19923238.
  29. ^ Kato, Hideaki; Takeuchi, Yoshimi; Tsumuraya, Yoichi; Hashimoto, Yohichi; Nakano, Hirofumi; Kováč, Pavol (2003-02-11). "In vitro biosynthesis of galactans by membrane-bound galactosyltransferase from radish (Raphanus sativus L.) seedlings". Planta. 217 (2): 271–282. Bibcode:2003Plant.217..271K. doi:10.1007/s00425-003-0978-7. ISSN 0032-0935. PMID 12783335. S2CID 5783849.
  30. ^ Showalter, Allan M.; Basu, Debarati (2016-06-15). "Extensin and Arabinogalactan-Protein Biosynthesis: Glycosyltransferases, Research Challenges, and Biosensors". Frontiers in Plant Science. 7: 814. doi:10.3389/fpls.2016.00814. ISSN 1664-462X. PMC 4908140. PMID 27379116.
  31. ^ Egelund, Jack; Obel, Nicolai; Ulvskov, Peter; Geshi, Naomi; Pauly, Markus; Bacic, Antony; Petersen, Bent Larsen (2007-03-31). "Molecular characterization of two Arabidopsis thaliana glycosyltransferase mutants, rra1 and rra2, which have a reduced residual arabinose content in a polymer tightly associated with the cellulosic wall residue". Plant Molecular Biology. 64 (4): 439–451. doi:10.1007/s11103-007-9162-y. ISSN 0167-4412. PMID 17401635. S2CID 11643754.
  32. ^ a b Qu, Yongmei; Egelund, Jack; Gilson, Paul R.; Houghton, Fiona; Gleeson, Paul A.; Schultz, Carolyn J.; Bacic, Antony (2008-06-12). "Identification of a novel group of putative Arabidopsis thaliana β-(1,3)-galactosyltransferases". Plant Molecular Biology. 68 (1–2): 43–59. doi:10.1007/s11103-008-9351-3. ISSN 0167-4412. PMID 18548197. S2CID 25896609.
  33. ^ Basu, Debarati; Tian, Lu; Wang, Wuda; Bobbs, Shauni; Herock, Hayley; Travers, Andrew; Showalter, Allan M. (December 2015). "A small multigene hydroxyproline-O-galactosyltransferase family functions in arabinogalactan-protein glycosylation, growth and development in Arabidopsis". BMC Plant Biology. 15 (1): 295. doi:10.1186/s12870-015-0670-7. ISSN 1471-2229. PMC 4687291. PMID 26690932.
  34. ^ Ogawa-Ohnishi, Mari; Matsubayashi, Yoshikatsu (2015-02-24). "Identification of three potent hydroxyprolineO-galactosyltransferases in Arabidopsis". The Plant Journal. 81 (5): 736–746. doi:10.1111/tpj.12764. ISSN 0960-7412. PMID 25600942.
  35. ^ a b Knoch, Eva; Dilokpimol, Adiphol; Tryfona, Theodora; Poulsen, Christian P.; Xiong, Guangyan; Harholt, Jesper; Petersen, Bent L.; Ulvskov, Peter; Hadi, Masood Z. (2013-11-29). "A β-glucuronosyltransferase from Arabidopsis thaliana involved in biosynthesis of type II arabinogalactan has a role in cell elongation during seedling growth". The Plant Journal. 76 (6): 1016–1029. doi:10.1111/tpj.12353. ISSN 0960-7412. PMID 24128328.
  36. ^ Dilokpimol, Adiphol; Geshi, Naomi (2014-04-16). "Arabidopsis thalianaglucuronosyltransferase in family GT14". Plant Signaling & Behavior. 9 (6): e28891. Bibcode:2014PlSiB...9E8891D. doi:10.4161/psb.28891. ISSN 1559-2324. PMC 4091549. PMID 24739253.
  37. ^ Wu, Yingying; Williams, Matthew; Bernard, Sophie; Driouich, Azeddine; Showalter, Allan M.; Faik, Ahmed (2010-04-30). "Functional identification of two nonredundant Arabidopsis alpha(1,2)fucosyltransferases specific to arabinogalactan proteins". The Journal of Biological Chemistry. 285 (18): 13638–13645. doi:10.1074/jbc.M110.102715. ISSN 1083-351X. PMC 2859526. PMID 20194500.
  38. ^ Tryfona, Theodora; Theys, Tina E.; Wagner, Tanya; Stott, Katherine; Keegstra, Kenneth; Dupree, Paul (2014-03-25). "Characterisation of FUT4 and FUT6 α-(1→2)-Fucosyltransferases Reveals that Absence of Root Arabinogalactan Fucosylation Increases Arabidopsis Root Growth Salt Sensitivity". PLOS ONE. 9 (3): e93291. Bibcode:2014PLoSO...993291T. doi:10.1371/journal.pone.0093291. ISSN 1932-6203. PMC 3965541. PMID 24667545.
  39. ^ Dilokpimol, Adiphol; Poulsen, Christian; Vereb, György; Kaneko, Satoshi; Schulz, Alexander; Geshi, Naomi (2014). "Galactosyltransferases from Arabidopsis thaliana in the biosynthesis of type II arabinogalactan: molecular interaction enhances enzyme activity". BMC Plant Biology. 14 (1): 90. doi:10.1186/1471-2229-14-90. ISSN 1471-2229. PMC 4234293. PMID 24693939.
  40. ^ a b c d Oxley, D.; Bacic, A. (1999-12-07). "Structure of the glycosylphosphatidylinositol anchor of an arabinogalactan protein from Pyrus communis suspension-cultured cells". Proceedings of the National Academy of Sciences of the United States of America. 96 (25): 14246–14251. Bibcode:1999PNAS...9614246O. doi:10.1073/pnas.96.25.14246. ISSN 0027-8424. PMC 24422. PMID 10588691.
  41. ^ a b Yeats, Trevor H.; Bacic, Antony; Johnson, Kim L. (August 2018). "Plant glycosylphosphatidylinositol anchored proteins at the plasma membrane-cell wall nexus: Plant GPI-anchored proteins". Journal of Integrative Plant Biology. 60 (8): 649–669. doi:10.1111/jipb.12659. hdl:11343/283902. ISSN 1744-7909. PMID 29667761. S2CID 4949024.
  42. ^ Imhof, Isabella; Flury, Isabelle; Vionnet, Christine; Roubaty, Carole; Egger, Diane; Conzelmann, Andreas (2004-05-07). "Glycosylphosphatidylinositol (GPI) proteins of Saccharomyces cerevisiae contain ethanolamine phosphate groups on the alpha1,4-linked mannose of the GPI anchor". The Journal of Biological Chemistry. 279 (19): 19614–19627. doi:10.1074/jbc.M401873200. ISSN 0021-9258. PMID 14985347.
  43. ^ Ferguson, M.; Homans, S.; Dwek, R.; Rademacher, T. (1988-02-12). "Glycosyl-phosphatidylinositol moiety that anchors Trypanosoma brucei variant surface glycoprotein to the membrane". Science. 239 (4841): 753–759. Bibcode:1988Sci...239..753F. doi:10.1126/science.3340856. ISSN 0036-8075. PMID 3340856.
  44. ^ Ferguson, M. A. (September 1999). "The structure, biosynthesis and functions of glycosylphosphatidylinositol anchors, and the contributions of trypanosome research". Journal of Cell Science. 112 (17): 2799–2809. doi:10.1242/jcs.112.17.2799. ISSN 0021-9533. PMID 10444375.
  45. ^ Strasser, Richard (2016-02-23). "Plant protein glycosylation". Glycobiology. 26 (9): 926–939. doi:10.1093/glycob/cww023. ISSN 0959-6658. PMC 5045529. PMID 26911286.
  46. ^ Muniz, M.; Zurzolo, C. (2014-06-06). "Sorting of GPI-anchored proteins from yeast to mammals - common pathways at different sites?". Journal of Cell Science. 127 (13): 2793–2801. doi:10.1242/jcs.148056. ISSN 0021-9533. PMID 24906797.
  47. ^ a b c d e Qu, Yongmei; Egelund, Jack; Gilson, Paul R.; Houghton, Fiona; Gleeson, Paul A.; Schultz, Carolyn J.; Bacic, Antony (2008-09-01). "Identification of a novel group of putative Arabidopsis thaliana β-(1,3)-galactosyltransferases". Plant Molecular Biology. 68 (1–2): 43–59. doi:10.1007/s11103-008-9351-3. ISSN 0167-4412. PMID 18548197. S2CID 25896609.
  48. ^ Egelund, Jack; Ellis, Miriam; Doblin, Monika; Qu, Yongmei; Bacic, Antony (2010). Ulvskov, Peter (ed.). Annual Plant Reviews. Wiley-Blackwell. pp. 213–234. doi:10.1002/9781444391015.ch7. ISBN 9781444391015.
  49. ^ Basu, Debarati; Liang, Yan; Liu, Xiao; Himmeldirk, Klaus; Faik, Ahmed; Kieliszewski, Marcia; Held, Michael; Showalter, Allan M. (2013-04-05). "Functional Identification of a Hydroxyproline-O-galactosyltransferase Specific for Arabinogalactan Protein Biosynthesis in Arabidopsis". Journal of Biological Chemistry. 288 (14): 10132–10143. doi:10.1074/jbc.m112.432609. ISSN 0021-9258. PMC 3617256. PMID 23430255.
  50. ^ a b Ogawa-Ohnishi, Mari; Matsubayashi, Yoshikatsu (2015-03-01). "Identification of three potent hydroxyproline O-galactosyltransferases in Arabidopsis". The Plant Journal. 81 (5): 736–746. doi:10.1111/tpj.12764. ISSN 1365-313X. PMID 25600942.
  51. ^ a b Suzuki, Toshiya; Narciso, Joan Oñate; Zeng, Wei; Meene, Allison van de; Yasutomi, Masayuki; Takemura, Shunsuke; Lampugnani, Edwin R.; Doblin, Monika S.; Bacic, Antony (2017-01-01). "KNS4/UPEX1: A Type II Arabinogalactan β-(1,3)-Galactosyltransferase Required for Pollen Exine Development". Plant Physiology. 173 (1): 183–205. doi:10.1104/pp.16.01385. ISSN 0032-0889. PMC 5210738. PMID 27837085.
  52. ^ a b c Geshi, Naomi; Johansen, Jorunn N.; Dilokpimol, Adiphol; Rolland, Aurélia; Belcram, Katia; Verger, Stéphane; Kotake, Toshihisa; Tsumuraya, Yoichi; Kaneko, Satoshi (2013-10-01). "A galactosyltransferase acting on arabinogalactan protein glycans is essential for embryo development in Arabidopsis". The Plant Journal. 76 (1): 128–137. doi:10.1111/tpj.12281. ISSN 1365-313X. PMID 23837821.
  53. ^ Dilokpimol, Adiphol; Poulsen, Christian Peter; Vereb, György; Kaneko, Satoshi; Schulz, Alexander; Geshi, Naomi (2014-04-03). "Galactosyltransferases from Arabidopsis thaliana in the biosynthesis of type II arabinogalactan: molecular interaction enhances enzyme activity". BMC Plant Biology. 14: 90. doi:10.1186/1471-2229-14-90. ISSN 1471-2229. PMC 4234293. PMID 24693939.
  54. ^ Dilokpimol, Adiphol; Geshi, Naomi (2014-06-01). "Arabidopsis thaliana glucuronosyltransferase in family GT14". Plant Signaling & Behavior. 9 (6): e28891. Bibcode:2014PlSiB...9E8891D. doi:10.4161/psb.28891. PMC 4091549. PMID 24739253.
  55. ^ a b Wu, Yingying; Williams, Matthew; Bernard, Sophie; Driouich, Azeddine; Showalter, Allan M.; Faik, Ahmed (2010-04-30). "Functional Identification of Two Nonredundant Arabidopsis α(1,2)Fucosyltransferases Specific to Arabinogalactan Proteins". Journal of Biological Chemistry. 285 (18): 13638–13645. doi:10.1074/jbc.m110.102715. ISSN 0021-9258. PMC 2859526. PMID 20194500.
  56. ^ a b Liang, Yan; Basu, Debarati; Pattathil, Sivakumar; Xu, Wen-liang; Venetos, Alexandra; Martin, Stanton L.; Faik, Ahmed; Hahn, Michael G.; Showalter, Allan M. (2013-12-01). "Biochemical and physiological characterization of fut4 and fut6 mutants defective in arabinogalactan-protein fucosylation in Arabidopsis". Journal of Experimental Botany. 64 (18): 5537–5551. doi:10.1093/jxb/ert321. ISSN 0022-0957. PMC 3871811. PMID 24127514.
  57. ^ a b Gille, Sascha; Sharma, Vaishali; Baidoo, Edward E.K.; Keasling, Jay D.; Scheller, Henrik Vibe; Pauly, Markus (2013-07-01). "Arabinosylation of a Yariv-Precipitable Cell Wall Polymer Impacts Plant Growth as Exemplified by the Arabidopsis Glycosyltransferase Mutant ray1". Molecular Plant. 6 (4): 1369–1372. doi:10.1093/mp/sst029. ISSN 1674-2052. PMID 23396039.
  58. ^ a b Saha, Dipjyoti; Bhattacharya, Suvendu (December 2010). "Hydrocolloids as thickening and gelling agents in food: a critical review". Journal of Food Science and Technology. 47 (6): 587–597. doi:10.1007/s13197-010-0162-6. ISSN 0022-1155. PMC 3551143. PMID 23572691.
  59. ^ a b Barclay, Thomas G.; Day, Candace Minhthu; Petrovsky, Nikolai; Garg, Sanjay (October 2019). "Review of polysaccharide particle-based functional drug delivery". Carbohydrate Polymers. 221: 94–112. doi:10.1016/j.carbpol.2019.05.067. PMC 6626612. PMID 31227171.
  60. ^ a b Aizat, Wan M.; Preuss, James M.; Johnson, Alexander A.T.; Tester, Mark A.; Schultz, Carolyn J. (November 2011). "Investigation of a His-rich arabinogalactan-protein for micronutrient biofortification of cereal grain". Physiologia Plantarum. 143 (3): 271–286. doi:10.1111/j.1399-3054.2011.01499.x. PMID 21707638.
  61. ^ a b Fujita, Kiyotaka; Sasaki, Yuki; Kitahara, Kanefumi (September 2019). "Degradation of plant arabinogalactan proteins by intestinal bacteria: characteristics and functions of the enzymes involved". Applied Microbiology and Biotechnology. 103 (18): 7451–7457. doi:10.1007/s00253-019-10049-0. ISSN 0175-7598. PMID 31384991. S2CID 199451378.
  62. ^ a b Singha, Prajjal K.; Roy, Somenath; Dey, Satyahari (April 2007). "Protective activity of andrographolide and arabinogalactan proteins from Andrographis paniculata Nees. against ethanol-induced toxicity in mice". Journal of Ethnopharmacology. 111 (1): 13–21. doi:10.1016/j.jep.2006.10.026. PMID 17127022.
  63. ^ Fincher, G B; Stone, B A; Clarke, A E (1983-06-01). "Arabinogalactan-Proteins: Structure, Biosynthesis, and Function". Annual Review of Plant Physiology. 34 (1): 47–70. doi:10.1146/annurev.pp.34.060183.000403. ISSN 0066-4294.
  64. ^ Ma, Yingxuan; Zeng, Wei; Bacic, Antony; Johnson, Kim (2018). "AGPs Through Time and Space". Annual Plant Reviews online. Vol. 3. pp. 767–804. doi:10.1002/9781119312994.apr0608. ISBN 9781119312994. ISSN 2639-3832. S2CID 104384164.
  65. ^ Nguema-Ona, Eric; Vicré-Gibouin, Maïté; Cannesan, Marc-Antoine; Driouich, Azeddine (August 2013). "Arabinogalactan proteins in root–microbe interactions". Trends in Plant Science. 18 (8): 440–449. doi:10.1016/j.tplants.2013.03.006. ISSN 1878-4372. PMID 23623239. S2CID 8085638.
  66. ^ Filmus, Jorge; Capurro, Mariana; Rast, Jonathan (2008). "Glypicans". Genome Biology. 9 (5): 224. doi:10.1186/gb-2008-9-5-224. ISSN 1465-6906. PMC 2441458. PMID 18505598.
  67. ^ Schaefer, Liliana; Schaefer, Roland M. (2009-06-10). "Proteoglycans: from structural compounds to signaling molecules". Cell and Tissue Research. 339 (1): 237–246. doi:10.1007/s00441-009-0821-y. ISSN 0302-766X. PMID 19513755. S2CID 20358779.
  68. ^ Tan, Li; Showalter, Allan M.; Egelund, Jack; Hernandez-Sanchez, Arianna; Doblin, Monika S.; Bacic, Antony (2012). "Arabinogalactan-proteins and the research challenges for these enigmatic plant cell surface proteoglycans". Frontiers in Plant Science. 3: 140. doi:10.3389/fpls.2012.00140. ISSN 1664-462X. PMC 3384089. PMID 22754559.
  69. ^ Kitazawa, Kiminari; Tryfona, Theodora; Yoshimi, Yoshihisa; Hayashi, Yoshihiro; Kawauchi, Susumu; Antonov, Liudmil; Tanaka, Hiroshi; Takahashi, Takashi; Kaneko, Satoshi (March 2013). "β-Galactosyl Yariv Reagent Binds to the β-1,3-Galactan of Arabinogalactan Proteins". Plant Physiology. 161 (3): 1117–1126. doi:10.1104/pp.112.211722. ISSN 0032-0889. PMC 3585584. PMID 23296690.
  70. ^ Yariv, J; Rapport, MM; Graf, L (1962-11-01). "The interaction of glycosides and saccharides with antibody to the corresponding phenylazo glycosides". Biochemical Journal. 85 (2): 383–388. doi:10.1042/bj0850383. ISSN 0006-2936. PMC 1243744. PMID 14002491.
  71. ^ Tang, X.-C. (2006-07-07). "The role of arabinogalactan proteins binding to Yariv reagents in the initiation, cell developmental fate, and maintenance of microspore embryogenesis in Brassica napus L. cv. Topas". Journal of Experimental Botany. 57 (11): 2639–2650. doi:10.1093/jxb/erl027. ISSN 0022-0957. PMID 16829548.
  72. ^ Willats, William G.T.; Knox, J. Paul (June 1996). "A role for arabinogalactan-proteins in plant cell expansion: evidence from studies on the interaction of beta-glucosyl Yariv reagent with seedlings of Arabidopsis thaliana". The Plant Journal. 9 (6): 919–925. doi:10.1046/j.1365-313x.1996.9060919.x. ISSN 0960-7412. PMID 8696368.
  73. ^ Chapman, Audrey; Blervacq, Anne-Sophie; Vasseur, Jacques; Hilbert, Jean-Louis (2000-08-10). "Arabinogalactan-proteins in Cichorium somatic embryogenesis: effect of β-glucosyl Yariv reagent and epitope localisation during embryo development". Planta. 211 (3): 305–314. Bibcode:2000Plant.211..305C. doi:10.1007/s004250000299. ISSN 0032-0935. PMID 10987548. S2CID 23116408.
  74. ^ Zagorchev, L; Stoineva, R; Odjakova, M (2013). "Changes in arabinogalactan proteins during somatic embryogenesis In suspension In vitro Cultures of Dactylis glomerata L." (PDF). Bulgarian Journal of Agricultural Science. 17 (2): 35–38. ISSN 1310-0351.
  75. ^ Ruprecht, Colin; Bartetzko, Max P.; Senf, Deborah; Dallabernadina, Pietro; Boos, Irene; Andersen, Mathias C.F.; Kotake, Toshihisa; Knox, J. Paul; Hahn, Michael G. (November 2017). "A Synthetic Glycan Microarray Enables Epitope Mapping of Plant Cell Wall Glycan-Directed Antibodies". Plant Physiology. 175 (3): 1094–1104. doi:10.1104/pp.17.00737. ISSN 0032-0889. PMC 5664464. PMID 28924016.
  76. ^ Seifert, Georg J.; Roberts, Keith (June 2007). "The Biology of Arabinogalactan Proteins". Annual Review of Plant Biology. 58 (1): 137–161. doi:10.1146/annurev.arplant.58.032806.103801. ISSN 1543-5008. PMID 17201686.
  77. ^ van Hengel, Arjon J.; Roberts, Keith (October 2003). "AtAGP30, an arabinogalactan-protein in the cell walls of the primary root, plays a role in root regeneration and seed germination". The Plant Journal. 36 (2): 256–270. doi:10.1046/j.1365-313x.2003.01874.x. ISSN 0960-7412. PMID 14535889.
  78. ^ Coimbra, Sílvia; Costa, Mário; Mendes, Marta Adelina; Pereira, Ana Marta; Pinto, João; Pereira, Luís Gustavo (2010-02-17). "Early germination of Arabidopsis pollen in a double null mutant for the arabinogalactan protein genes AGP6 and AGP11". Sexual Plant Reproduction. 23 (3): 199–205. doi:10.1007/s00497-010-0136-x. ISSN 0934-0882. PMID 20162305. S2CID 32823162.
  79. ^ Suzuki, Toshiya; Narciso, Joan Oñate; Zeng, Wei; van de Meene, Allison; Yasutomi, Masayuki; Takemura, Shunsuke; Lampugnani, Edwin R.; Doblin, Monika S.; Bacic, Antony (2016-11-09). "KNS4/UPEX1: A Type II Arabinogalactan β-(1,3)-Galactosyltransferase Required for Pollen Exine Development". Plant Physiology. 173 (1): 183–205. doi:10.1104/pp.16.01385. ISSN 0032-0889. PMC 5210738. PMID 27837085.
  80. ^ Lamport, Derek T. A.; Várnai, Péter (January 2013). "Periplasmic arabinogalactan glycoproteins act as a calcium capacitor that regulates plant growth and development". New Phytologist. 197 (1): 58–64. doi:10.1111/nph.12005. ISSN 0028-646X. PMID 23106282.
  81. ^ Lamport, Derek T. A.; Tan, Li; Held, Michael; Kieliszewski, Marcia J. (2020-02-09). "Phyllotaxis Turns Over a New Leaf—A New Hypothesis". International Journal of Molecular Sciences. 21 (3): 1145. doi:10.3390/ijms21031145. ISSN 1422-0067. PMC 7037126. PMID 32050457.
  82. ^ Lopez-Hernandez, Federico; Tryfona, Theodora; Rizza, Annalisa; Yu, Xiaolan L.; Harris, Matthew O.B.; Webb, Alex A.R.; Kotake, Toshihisa; Dupree, Paul (October 2020). "Calcium Binding by Arabinogalactan Polysaccharides Is Important for Normal Plant Development". The Plant Cell. 32 (10): 3346–3369. doi:10.1105/tpc.20.00027. ISSN 1040-4651. PMC 7534474. PMID 32769130.
  83. ^ a b Huber, O.; Sumper, M. (1994-09-15). "Algal-CAMs: isoforms of a cell adhesion molecule in embryos of the alga Volvox with homology to Drosophila fasciclin I". The EMBO Journal. 13 (18): 4212–4222. doi:10.1002/j.1460-2075.1994.tb06741.x. ISSN 0261-4189. PMC 395348. PMID 7925267.
  84. ^ Seifert, Georg J. (2018-05-31). "Fascinating Fasciclins: A Surprisingly Widespread Family of Proteins that Mediate Interactions between the Cell Exterior and the Cell Surface". International Journal of Molecular Sciences. 19 (6): 1628. doi:10.3390/ijms19061628. ISSN 1422-0067. PMC 6032426. PMID 29857505.
  85. ^ Poon, Simon; Heath, Robyn Louise; Clarke, Adrienne Elizabeth (2012-08-02). "A Chimeric Arabinogalactan Protein Promotes Somatic Embryogenesis in Cotton Cell Culture". Plant Physiology. 160 (2): 684–695. doi:10.1104/pp.112.203075. ISSN 0032-0889. PMC 3461548. PMID 22858635.
  86. ^ Toonen, Marcel A. J.; Schmidt, Ed D. L.; van Kammen, Ab; de Vries, Sacco C. (1997-09-26). "Promotive and inhibitory effects of diverse arabinogalactan proteins on Daucus carota L. somatic embryogenesis". Planta. 203 (2): 188–195. Bibcode:1997Plant.203..188T. doi:10.1007/s004250050181. ISSN 0032-0935. S2CID 35053257.
  87. ^ Hu, Ying; Qin, Yuan; Zhao, Jie (2006-10-06). "Localization of an arabinogalactan protein epitope and the effects of Yariv phenylglycoside during zygotic embryo development of Arabidopsis thaliana". Protoplasma. 229 (1): 21–31. doi:10.1007/s00709-006-0185-z. ISSN 0033-183X. PMID 17019527. S2CID 9707077.
  88. ^ Qin, Y. (2006-01-31). "Localization of arabinogalactan proteins in egg cells, zygotes, and two-celled proembryos and effects of -D-glucosyl Yariv reagent on egg cell fertilization and zygote division in Nicotiana tabacum L." Journal of Experimental Botany. 57 (9): 2061–2074. doi:10.1093/jxb/erj159. ISSN 0022-0957. PMID 16720612.
  89. ^ Steinmacher, Douglas A.; Saare-Surminski, Katja; Lieberei, Reinhard (2012-06-19). "Arabinogalactan proteins and the extracellular matrix surface network during peach palm somatic embryogenesis". Physiologia Plantarum. 146 (3): 336–349. doi:10.1111/j.1399-3054.2012.01642.x. ISSN 0031-9317. PMID 22574975.
  90. ^ Pan, Xiao; Yang, Xiao; Lin, Guimei; Zou, Ru; Chen, Houbin; Šamaj, Jozef; Xu, Chunxiang (2011-05-24). "Ultrastructural changes and the distribution of arabinogalactan proteins during somatic embryogenesis of banana (Musa spp. AAA cv. 'Yueyoukang 1')". Physiologia Plantarum. 142 (4): 372–389. doi:10.1111/j.1399-3054.2011.01478.x. ISSN 0031-9317. PMID 21496030.
  91. ^ Duchow, Stefanie; Dahlke, Renate I.; Geske, Thomas; Blaschek, Wolfgang; Classen, Birgit (November 2016). "Arabinogalactan-proteins stimulate somatic embryogenesis and plant propagation of Pelargonium sidoides". Carbohydrate Polymers. 152: 149–155. doi:10.1016/j.carbpol.2016.07.015. ISSN 0144-8617. PMID 27516259.
  92. ^ Hallmann, A.; Kirk, D. L. (December 2000). "The developmentally regulated ECM glycoprotein ISG plays an essential role in organizing the ECM and orienting the cells of Volvox". Journal of Cell Science. 113 (24): 4605–4617. doi:10.1242/jcs.113.24.4605. ISSN 0021-9533. PMID 11082052.
  93. ^ Pereira, Ana Marta; Lopes, Ana Lúcia; Coimbra, Sílvia (2016-07-14). "JAGGER, an AGP essential for persistent synergid degeneration and polytubey block in Arabidopsis". Plant Signaling & Behavior. 11 (8): e1209616. Bibcode:2016PlSiB..11E9616P. doi:10.1080/15592324.2016.1209616. ISSN 1559-2324. PMC 5022411. PMID 27413888.
  94. ^ Levitin, Bella; Richter, Dganit; Markovich, Inbal; Zik, Moriyah (November 2008). "Arabinogalactan proteins 6 and 11 are required for stamen and pollen function in Arabidopsis". The Plant Journal. 56 (3): 351–363. doi:10.1111/j.1365-313x.2008.03607.x. ISSN 0960-7412. PMID 18644001.
  95. ^ Coimbra, S.; Costa, M.; Jones, B.; Mendes, M. A.; Pereira, L. G. (2009-05-11). "Pollen grain development is compromised in Arabidopsis agp6 agp11 null mutants". Journal of Experimental Botany. 60 (11): 3133–3142. doi:10.1093/jxb/erp148. ISSN 0022-0957. PMC 2718217. PMID 19433479.
  96. ^ Acosta-García, Gerardo; Vielle-Calzada, Jean-Philippe (2004-09-17). "A Classical Arabinogalactan Protein Is Essential for the Initiation of Female Gametogenesis in Arabidopsis". The Plant Cell. 16 (10): 2614–2628. doi:10.1105/tpc.104.024588. ISSN 1040-4651. PMC 520959. PMID 15377758.
  97. ^ Demesa-Arévalo, Edgar; Vielle-Calzada, Jean-Philippe (April 2013). "The Classical Arabinogalactan Protein AGP18 Mediates Megaspore Selection in Arabidopsis". The Plant Cell. 25 (4): 1274–1287. doi:10.1105/tpc.112.106237. ISSN 1040-4651. PMC 3663267. PMID 23572547.
  98. ^ a b Li, Yunjing; Liu, Diqiu; Tu, Lili; Zhang, Xianlong; Wang, Li; Zhu, Longfu; Tan, Jiafu; Deng, Fenglin (2009-12-30). "Suppression of GhAGP4 gene expression repressed the initiation and elongation of cotton fiber". Plant Cell Reports. 29 (2): 193–202. doi:10.1007/s00299-009-0812-1. ISSN 0721-7714. PMID 20041253. S2CID 1341378.
  99. ^ Mashiguchi, Kiyoshi; Asami, Tadao; Suzuki, Yoshihito (2009-11-23). "Genome-Wide Identification, Structure and Expression Studies, and Mutant Collection of 22 Early Nodulin-Like Protein Genes in Arabidopsis". Bioscience, Biotechnology, and Biochemistry. 73 (11): 2452–2459. doi:10.1271/bbb.90407. ISSN 0916-8451. PMID 19897921. S2CID 27449840.
  100. ^ Hou, Yingnan; Guo, Xinyang; Cyprys, Philipp; Zhang, Ying; Bleckmann, Andrea; Cai, Le; Huang, Qingpei; Luo, Yu; Gu, Hongya (September 2016). "Maternal ENODLs Are Required for Pollen Tube Reception in Arabidopsis". Current Biology. 26 (17): 2343–2350. Bibcode:2016CBio...26.2343H. doi:10.1016/j.cub.2016.06.053. ISSN 0960-9822. PMC 5522746. PMID 27524487.
  101. ^ Lin, Sue; Dong, Heng; Zhang, Fang; Qiu, Lin; Wang, Fangzhan; Cao, Jiashu; Huang, Li (2014-01-31). "BcMF8, a putative arabinogalactan protein-encoding gene, contributes to pollen wall development, aperture formation and pollen tube growth in Brassica campestris". Annals of Botany. 113 (5): 777–788. doi:10.1093/aob/mct315. ISSN 1095-8290. PMC 3962243. PMID 24489019.
  102. ^ Lin, Sue; Yue, Xiaoyan; Miao, Yingjing; Yu, Youjian; Dong, Heng; Huang, Li; Cao, Jiashu (2018-03-09). "The distinct functions of two classical arabinogalactan proteins BcMF8 and BcMF18 during pollen wall development in Brassica campestris". The Plant Journal. 94 (1): 60–76. doi:10.1111/tpj.13842. ISSN 0960-7412. PMID 29385650.
  103. ^ Cheung, Alice Y; Wang, Hong; Wu, Hen-ming (August 1995). "A floral transmitting tissue-specific glycoprotein attracts pollen tubes and stimulates their growth". Cell. 82 (3): 383–393. doi:10.1016/0092-8674(95)90427-1. ISSN 0092-8674. PMID 7634328. S2CID 17604437.
  104. ^ Nathan Hancock, C.; Kent, Lia; McClure, Bruce A. (2005-08-08). "The stylar 120 kDa glycoprotein is required for S-specific pollen rejection in Nicotiana". The Plant Journal. 43 (5): 716–723. doi:10.1111/j.1365-313x.2005.02490.x. ISSN 0960-7412. PMID 16115068.
  105. ^ Tan, Hexin; Liang, Wanqi; Hu, Jianping; Zhang, Dabing (June 2012). "MTR1 Encodes a Secretory Fasciclin Glycoprotein Required for Male Reproductive Development in Rice". Developmental Cell. 22 (6): 1127–1137. doi:10.1016/j.devcel.2012.04.011. ISSN 1534-5807. PMID 22698279.
  106. ^ Yang, Jie; Sardar, Harjinder S.; McGovern, Kathleen R.; Zhang, Yizhu; Showalter, Allan M. (2007-01-08). "A lysine-rich arabinogalactan protein in Arabidopsis is essential for plant growth and development, including cell division and expansion". The Plant Journal. 49 (4): 629–640. doi:10.1111/j.1365-313x.2006.02985.x. ISSN 0960-7412. PMID 17217456.
  107. ^ Tan, Li; Eberhard, Stefan; Pattathil, Sivakumar; Warder, Clayton; Glushka, John; Yuan, Chunhua; Hao, Zhangying; Zhu, Xiang; Avci, Utku (January 2013). "An Arabidopsis Cell Wall Proteoglycan Consists of Pectin and Arabinoxylan Covalently Linked to an Arabinogalactan Protein". The Plant Cell. 25 (1): 270–287. doi:10.1105/tpc.112.107334. ISSN 1040-4651. PMC 3584541. PMID 23371948.
  108. ^ Johnson, Kim L.; Kibble, Natalie A. J.; Bacic, Antony; Schultz, Carolyn J. (2011-09-22). "A Fasciclin-Like Arabinogalactan-Protein (FLA) Mutant of Arabidopsis thaliana, fla1, Shows Defects in Shoot Regeneration". PLOS ONE. 6 (9): e25154. Bibcode:2011PLoSO...625154J. doi:10.1371/journal.pone.0025154. ISSN 1932-6203. PMC 3178619. PMID 21966441.
  109. ^ Shi, Huazhong; Kim, YongSig; Guo, Yan; Stevenson, Becky; Zhu, Jian-Kang (2002-12-13). "The Arabidopsis SOS5 Locus Encodes a Putative Cell Surface Adhesion Protein and Is Required for Normal Cell Expansion". The Plant Cell. 15 (1): 19–32. doi:10.1105/tpc.007872. ISSN 1040-4651. PMC 143448. PMID 12509519.
  110. ^ Harpaz-Saad, Smadar; McFarlane, Heather E.; Xu, Shouling; Divi, Uday K.; Forward, Bronwen; Western, Tamara L.; Kieber, Joseph J. (2011-10-10). "Cellulose synthesis via the FEI2 RLK/SOS5 pathway and CELLULOSE SYNTHASE 5 is required for the structure of seed coat mucilage in Arabidopsis". The Plant Journal. 68 (6): 941–953. doi:10.1111/j.1365-313x.2011.04760.x. ISSN 0960-7412. PMID 21883548.
  111. ^ Griffiths, Jonathan S.; Tsai, Allen Yi-Lun; Xue, Hui; Voiniciuc, Cătălin; Šola, Krešimir; Seifert, Georg J.; Mansfield, Shawn D.; Haughn, George W. (2014-05-07). "SALT-OVERLY SENSITIVE5 Mediates Arabidopsis Seed Coat Mucilage Adherence and Organization through Pectins". Plant Physiology. 165 (3): 991–1004. doi:10.1104/pp.114.239400. ISSN 0032-0889. PMC 4081351. PMID 24808103.
  112. ^ Griffiths, Jonathan S.; Crepeau, Marie-Jeanne; Ralet, Marie-Christine; Seifert, Georg J.; North, Helen M. (2016-07-29). "Dissecting Seed Mucilage Adherence Mediated by FEI2 and SOS5". Frontiers in Plant Science. 7: 1073. doi:10.3389/fpls.2016.01073. ISSN 1664-462X. PMC 4965450. PMID 27524986.
  113. ^ Xue, Hui; Veit, Christiane; Abas, Lindy; Tryfona, Theodora; Maresch, Daniel; Ricardi, Martiniano M.; Estevez, José Manuel; Strasser, Richard; Seifert, Georg J. (2017-06-13). "Arabidopsis thaliana FLA4 functions as a glycan-stabilized soluble factor via its carboxy-proximal Fasciclin 1 domain". The Plant Journal. 91 (4): 613–630. doi:10.1111/tpj.13591. ISSN 0960-7412. PMC 5575511. PMID 28482115.
  114. ^ Lee, Kieran J.D.; Sakata, Yoichi; Mau, Shaio-Lim; Pettolino, Filomena; Bacic, Antony; Quatrano, Ralph S.; Knight, Celia D.; Knox, J. Paul (2005-09-30). "Arabinogalactan Proteins Are Required for Apical Cell Extension in the Moss Physcomitrella patens". The Plant Cell. 17 (11): 3051–3065. doi:10.1105/tpc.105.034413. ISSN 1040-4651. PMC 1276029. PMID 16199618.
  115. ^ Kirchner, Thomas W.; Niehaus, Markus; Debener, Thomas; Schenk, Manfred K.; Herde, Marco (2017-09-22). "Efficient generation of mutations mediated by CRISPR/Cas9 in the hairy root transformation system of Brassica carinata". PLOS ONE. 12 (9): e0185429. Bibcode:2017PLoSO..1285429K. doi:10.1371/journal.pone.0185429. ISSN 1932-6203. PMC 5609758. PMID 28937992.
  116. ^ MacMillan, Colleen P.; Mansfield, Shawn D.; Stachurski, Zbigniew H.; Evans, Rob; Southerton, Simon G. (2010-02-24). "Fasciclin-like arabinogalactan proteins: specialization for stem biomechanics and cell wall architecture in Arabidopsis and Eucalyptus". The Plant Journal. 62 (4): 689–703. doi:10.1111/j.1365-313x.2010.04181.x. ISSN 0960-7412. PMID 20202165.
  117. ^ Motose, Hiroyasu; Sugiyama, Munetaka; Fukuda, Hiroo (June 2004). "A proteoglycan mediates inductive interaction during plant vascular development". Nature. 429 (6994): 873–878. Bibcode:2004Natur.429..873M. doi:10.1038/nature02613. ISSN 0028-0836. PMID 15215864. S2CID 4393158.
  118. ^ Wang, Haihai; Jiang, Chunmei; Wang, Cuiting; Yang, Yang; Yang, Lei; Gao, Xiaoyan; Zhang, Hongxia (2014-11-26). "Antisense expression of the fasciclin-like arabinogalactan protein FLA6 gene in Populus inhibits expression of its homologous genes and alters stem biomechanics and cell wall composition in transgenic trees". Journal of Experimental Botany. 66 (5): 1291–1302. doi:10.1093/jxb/eru479. ISSN 1460-2431. PMC 4339592. PMID 25428999.
  119. ^ Albert, Markus; Belastegui-Macadam, Xana; Kaldenhoff, Ralf (November 2006). "An attack of the plant parasite Cuscuta reflexa induces the expression of attAGP, an attachment protein of the host tomato". The Plant Journal. 48 (4): 548–556. doi:10.1111/j.1365-313x.2006.02897.x. ISSN 0960-7412. PMID 17076801.
  120. ^ Gaspar, Yolanda Maria; Nam, Jaesung; Schultz, Carolyn Jane; Lee, Lan-Ying; Gilson, Paul R.; Gelvin, Stanton B.; Bacic, Antony (August 2004). "Characterization of the Arabidopsis Lysine-Rich Arabinogalactan-Protein AtAGP17 Mutant ( rat1 ) That Results in a Decreased Efficiency of Agrobacterium Transformation". Plant Physiology. 135 (4): 2162–2171. doi:10.1104/pp.104.045542. ISSN 0032-0889. PMC 520787. PMID 15286287.
  121. ^ Tan, Li; Showalter, Allan M.; Egelund, Jack; Hernandez-Sanchez, Arianna; Doblin, Monika S.; Bacic, Antony (2012). "Arabinogalactan-proteins and the research challenges for these enigmatic plant cell surface proteoglycans". Frontiers in Plant Science. 3: 140. doi:10.3389/fpls.2012.00140. ISSN 1664-462X. PMC 3384089. PMID 22754559.
  122. ^ Johnson, Kim L.; Jones, Brian J.; Bacic, Antony; Schultz, Carolyn J. (2003-12-01). "The Fasciclin-Like Arabinogalactan Proteins of Arabidopsis. A Multigene Family of Putative Cell Adhesion Molecules". Plant Physiology. 133 (4): 1911–1925. doi:10.1104/pp.103.031237. ISSN 0032-0889. PMC 300743. PMID 14645732.
  123. ^ a b Basu, Debarati; Tian, Lu; Wang, Wuda; Bobbs, Shauni; Herock, Hayley; Travers, Andrew; Showalter, Allan M. (2015-12-21). "A small multigene hydroxyproline-O-galactosyltransferase family functions in arabinogalactan-protein glycosylation, growth and development in Arabidopsis". BMC Plant Biology. 15: 295. doi:10.1186/s12870-015-0670-7. ISSN 1471-2229. PMC 4687291. PMID 26690932.
  124. ^ Li, Wenhua L.; Liu, Yuanyuan; Douglas, Carl J. (2017-01-01). "Role of Glycosyltransferases in Pollen Wall Primexine Formation and Exine Patterning". Plant Physiology. 173 (1): 167–182. doi:10.1104/pp.16.00471. ISSN 0032-0889. PMC 5210704. PMID 27495941.
  125. ^ Knoch, Eva; Dilokpimol, Adiphol; Geshi, Naomi (2014). "Arabinogalactan proteins: focus on carbohydrate active enzymes". Frontiers in Plant Science. 5: 198. doi:10.3389/fpls.2014.00198. ISSN 1664-462X. PMC 4052742. PMID 24966860.