The families of pathogenesis-related proteins, their activities, and comparative analysis of PR-1 type proteins

In incompatible host-pathogen interactions, damage caused by the pathogen remains restricted as a result of the plant's defensive response. Most effective is the hypersensitive reaction, in which the cells around the infection site rapidly necrose. This response is associated with a coordinated and integrated set of metabolic alterations that are instrumental in impeding further pathogen ingress, as well as in enhancing the capacity of the host to limit subsequent infection by different types of pathogens [27, 77]. Altered ion fluxes across the plant cell membrane, generation of active oxygen species, changes in the phosphorylation state of regulatory proteins and transcriptional activation of plant defense systems culminate in cell death at the site of infection, local accumulation of phytoalexins and cell wall rigidification as a result of callose, lignin and suberin deposition [31, 89]. In addition, various novel proteins are induced which are collectively referred to as ``pathogenesis-related proteins '' (PRs). These PRs, defined as proteins coded for by the host plant but induced specifically in pathological or related situations [4, 81], do not only accumulate locally in the infected leaf, but are also induced systemically, associated with the development of systemic acquired resistance (SAR) against further infection by fungi, bacteria and viruses. Induction of PRs has been found in many plant species belonging to various families [78], suggestive of a general role for these proteins in adaptation to biotic stress conditions. SAR, likewise, is a generally occurring phenomenon, that engenders an enhancement of the defensive capacity of plants in response to necrotizing infections [70]. Since some of the tobacco PRs were identified as chitinases [45] and b-1,3-glucanases [38] with potential antifungal activity, it has often been suggested that the collective set of PRs may be effective in inhibiting pathogen growth, multiplication and/or spread, and be responsible for the state of SAR [42, 65]. Originally, five main classes of PRs (PR-1-5) were characterized by both biochemical and molecular-biological techniques in tobacco [9, 80]. Thereupon, in 1994 a unifying nomenclature for PRs was proposed based on their grouping into families sharing amino acid sequences, serological relationship, and/or enzymatic or biological activity. By then 11 families (PR-1--11) were recognized and classified for tobacco and tomato [81] (cf. Table 1). Criteria used for the inclusion of new families of PRs were that (i) protein(s) must be induced by a pathogen in tissues that do not normally express the protein(s), and (ii) induced expression must have been shown to occur in at least two different plant-pathogen combinations, or expression in a single plant-pathogen combination must have been confirmed independently in diaerent laboratories.

[1]  Franky R. G. Terras,et al.  Pathogen-induced systemic activation of a plant defensin gene in Arabidopsis follows a salicylic acid-independent pathway. , 1996, The Plant cell.

[2]  J. Antoniw,et al.  Purification of a tobacco leaf protein associated with resistance to virus infection [proceedings]. , 1978, Biochemical Society Transactions.

[3]  L. C. van Loon Induced resistance in plants and the role of pathogenesis-related proteins , 1997 .

[4]  F. Zimmermann,et al.  Sequence analysis of a 33·1 kb fragment from the left arm of Saccharomyces cerevisiae chromosome X, including putative proteins with leucine zippers, a fungal Zn(II)2‐Cys6 binuclear cluster domain and a putative α2‐SCB‐α2 binding site , 1995, Yeast.

[5]  J. Metraux,et al.  Systemic acquired resistance. , 1997, Annual review of phytopathology.

[6]  Jonathan D. G. Jones,et al.  Resistance gene-dependent plant defense responses. , 1996, The Plant cell.

[7]  B. Haendler,et al.  Mouse androgen‐dependent epididymal glycoprotein crisp‐1 (DE/AEG): Isolation, biochemical characterization, and expression in recombinant form , 1995, Molecular reproduction and development.

[8]  G. Kovalick,et al.  A novel cDNA from Drosophila encoding a protein with similarity to mammalian cysteine-rich secretory proteins, wasp venom antigen 5, and plant group 1 pathogenesis-related proteins. , 1997, Gene.

[9]  P. Højrup,et al.  Characterization of chitinases able to rescue somatic embryos of the temperature-sensitive carrot variant ts 11. , 1996, Plant molecular biology.

[10]  I. Chet,et al.  Molecular mechanisms of lytic enzymes involved in the biocontrol activity of Trichoderma harzianum , 1996 .

[11]  X. Wang,et al.  The PR5K receptor protein kinase from Arabidopsis thaliana is structurally related to a family of plant defense proteins. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[12]  P. D. Wit,et al.  The occurrence of host-, pathogen- and interaction-specific proteins in the apoplast of Cladosporium fulvum (syn. Fulvia fulva) infected tomato leaves , 1986 .

[13]  L. C. Loon 1 Occurrence and Properties of Plant Pathogenesis-Related Proteins , 1999 .

[14]  A. Molina,et al.  Lipid transfer proteins (nsLTPs) from barley and maize leaves are potent inhibitors of bacterial and fungal plant pathogens , 1993, FEBS letters.

[15]  D. Klessig,et al.  Signal perception and transduction in plant defense responses. , 1997, Genes & development.

[16]  M. Coscia,et al.  Sequence analysis and antigenic cross-reactivity of a venom allergen, antigen 5, from hornets, wasps, and yellow jackets. , 1993, Journal of immunology.

[17]  M. Israel,et al.  RTVP-1, a novel human gene with sequence similarity to genes of diverse species, is expressed in tumor cell lines of glial but not neuronal origin. , 1996, Gene.

[18]  C. Pieterse,et al.  A Novel Signaling Pathway Controlling Induced Systemic Resistance in Arabidopsis , 1998, Plant Cell.

[19]  M. Legrand,et al.  Biological function of ‘pathogenesis‐related’ proteins: four PR proteins of tobacco have 1,3‐β‐glucanase activity , 1987, The EMBO journal.

[20]  R. Goodman,et al.  The hypersensitive reaction in plants to pathogens: a resistance phenomenon. , 1994 .

[21]  Kaoru T. Yoshida,et al.  An Acidic 39-kDa Protein Secreted from Stigmas of Tobacco Has an Amino-Terminal Motif That is Conserved among Thaumatin-Like Proteins , 1997 .

[22]  J. Antoniw,et al.  The presence of pathogenesis-related proteins in callus of xanthi-nc tobacco , 1981 .

[23]  R. Fluhr,et al.  A major stylar matrix polypeptide (sp41) is a member of the pathogenesis‐related proteins superclass. , 1990, The EMBO journal.

[24]  K. Qing Systemic resistance induced by rhizosphere bacteria , 2001 .

[25]  P. Epple,et al.  An Arabidopsis thaliana Thionin Gene Is Inducible via a Signal Transduction Pathway Different from That for Pathogenesis-Related Proteins , 1995, Plant physiology.

[26]  C. Pieterse,et al.  Systemic resistance in Arabidopsis induced by biocontrol bacteria is independent of salicylic acid accumulation and pathogenesis-related gene expression. , 1996, The Plant cell.

[27]  A. Stintzi,et al.  Pathogenesis-Related PR-1 Proteins Are Antifungal (Isolation and Characterization of Three 14-Kilodalton Proteins of Tomato and of a Basic PR-1 of Tobacco with Inhibitory Activity against Phytophthora infestans) , 1995, Plant physiology.

[28]  J. Devereux,et al.  A comprehensive set of sequence analysis programs for the VAX , 1984, Nucleic Acids Res..

[29]  B. Haendler,et al.  Transcripts for cysteine-rich secretory protein-1 (CRISP-1; DE/AEG) and the novel related CRISP-3 are expressed under androgen control in the mouse salivary gland. , 1993, Endocrinology.

[30]  J. Ryals,et al.  Systemic Acquired Resistance. , 1996, The Plant cell.

[31]  F. Nagy,et al.  Evidence for a role of β‐1,3‐glucanase in dicot seed germination , 1994 .

[32]  J. Biggs,et al.  The human glioma pathogenesis-related protein is structurally related to plant pathogenesis-related proteins and its gene is expressed specifically in brain tumors. , 1995, Gene.

[33]  H. Linthorst Pathogenesis‐related proteins of plants , 1991 .

[34]  E. Ward,et al.  Increased tolerance to two oomycete pathogens in transgenic tobacco expressing pathogenesis-related protein 1a. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[35]  W. Broekaert,et al.  Antimicrobial Peptides from Plants , 1997 .

[36]  D. Hoffman Allergens in Hymenoptera venom. XXV: The amino acid sequences of antigen 5 molecules and the structural basis of antigenic cross-reactivity. , 1993, The Journal of allergy and clinical immunology.

[37]  P. Jekel,et al.  Primary structures of two ribonucleases from ginseng calluses , 1997, FEBS letters.

[38]  P. Epple,et al.  Overexpression of an endogenous thionin enhances resistance of Arabidopsis against Fusarium oxysporum. , 1997, The Plant cell.

[39]  P. Epple,et al.  Differential induction of the Arabidopsis thaliana Thi2.1 gene by Fusarium oxysporum f. sp. matthiolae. , 1998, Molecular plant-microbe interactions : MPMI.

[40]  B. Thomma,et al.  Separate jasmonate-dependent and salicylate-dependent defense-response pathways in Arabidopsis are essential for resistance to distinct microbial pathogens. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[41]  K. Pihakaski-Maunsbach,et al.  Immunolocalization of Antifreeze Proteins in Winter Rye Leaves, Crowns, and Roots by Tissue Printing , 1996, Plant physiology.

[42]  I. Somssich,et al.  Pathogenesis-Related Proteins and Plant Defense , 1997 .

[43]  T. Ushiki,et al.  Characterization of a human glycoprotein with a potential role in sperm-egg fusion: cDNA cloning, immunohistochemical localization, and chromosomal assignment of the gene (AEGL1). , 1996, Genomics.

[44]  C. Pieterse,et al.  Salicylic acid-independent plant defence pathways. , 1999, Trends in plant science.

[45]  J. Antoniw,et al.  Accumulation of a novel PR1 protein inNicotiana langsdorfiileaves in response to virus infection or treatment with salicylic acid , 1997 .

[46]  C. Wasternack,et al.  Wounding and chemicals induce expression of the Arabidopsis thaliana gene Thi2.1, encoding a fungal defense thionin, via the octadecanoid pathway , 1998, FEBS letters.

[47]  N. Doke,et al.  Identification of chitinase and osmotin-like protein as actin-binding proteins in suspension-cultured potato cells. , 1997, Plant & cell physiology.

[48]  T. P. King,et al.  cDNA cloning and primary structure of a white-face hornet venom allergen, antigen 5. , 1988, Proceedings of the National Academy of Sciences of the United States of America.

[49]  R. Dixon,et al.  Salicylic acid potentiates an agonist-dependent gain control that amplifies pathogen signals in the activation of defense mechanisms. , 1997, The Plant cell.

[50]  J. W. Liu,et al.  Bean ribonuclease-like pathogenesis-related protein genes (Ypr10) display complex patterns of developmental, dark-induced and exogenous-stimulus-dependent expression. , 1996, European journal of biochemistry.

[51]  A. Means,et al.  Molecular cloning of the cDNA for androgen-dependent sperm-coating glycoproteins secreted by the rat epididymis. , 1986, European journal of biochemistry.

[52]  N. Koshikawa,et al.  cDNA cloning of a novel trypsin inhibitor with similarity to pathogenesis-related proteins, and its frequent expression in human brain cancer cells. , 1998, Biochimica et biophysica acta.

[53]  K. Wüthrich,et al.  Structure comparison of human glioma pathogenesis-related protein GliPR and the plant pathogenesis-related protein P14a indicates a functional link between the human immune system and a plant defense system. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[54]  D. Hoffman,et al.  Allergens in Hymenoptera venom XXIV: the amino acid sequences of imported fire ant venom allergens Sol i II, Sol i III, and Sol i IV. , 1993, The Journal of allergy and clinical immunology.

[55]  Franky R. G. Terras,et al.  Analysis of two novel classes of plant antifungal proteins from radish (Raphanus sativus L.) seeds. , 1992, The Journal of biological chemistry.

[56]  Yasuyuki Yamada,et al.  Characterization of Polypeptides that Accumulate in Cultured Nicotiana tabacum Cells , 1990 .

[57]  S. Ásgeirsdóttir,et al.  The Sc7/Sc14 gene family of Schizophyllum commune codes for extracellular proteins specifically expressed during fruit-body formation. , 1993, Journal of general microbiology.

[58]  A. Segura,et al.  The defensive role of nonspecific lipid-transfer proteins in plants. , 1995, Trends in microbiology.

[59]  P. Goodfellow,et al.  Cloning and mapping of a testis-specific gene with sequence similarity to a sperm-coating glycoprotein gene. , 1989, Genomics.

[60]  L. Kjeldsen,et al.  SGP28, a novel matrix glycoprotein in specific granules of human neutrophils with similarity to a human testis‐specific gene product and to a rodent sperm‐coating glycoprotein , 1996, FEBS letters.

[61]  W. Driscoll,et al.  Purification and characterization of the primary acrosomal autoantigen of guinea pig epididymal spermatozoa. , 1988, Biology of reproduction.

[62]  P. Hasegawa,et al.  Characterization of osmotin : a thaumatin-like protein associated with osmotic adaptation in plant cells. , 1987, Plant physiology.

[63]  R. Dixon,et al.  Biologically induced systemic acquired resistance in Arabidopsis thaliana , 1994 .

[64]  A. Molina,et al.  Developmental and pathogen-induced expression of three barley genes encoding lipid transfer proteins. , 1993, The Plant journal : for cell and molecular biology.

[65]  C. Ryan Protease Inhibitors in Plants: Genes for Improving Defenses Against Insects and Pathogens , 1990 .

[66]  J. Antoniw,et al.  Comparison of three pathogenesis-related proteins from plants of two cultivars of tobacco infected with TMV , 1980 .

[67]  J. Vandekerckhove,et al.  A carrot somatic embryo mutant is rescued by chitinase. , 1992, The Plant cell.

[68]  P. Hasegawa,et al.  Regulation of protease inhibitors and plant defense , 1997 .

[69]  H. Bohlmann The Role of Thionins in Plant Protection , 1994 .

[70]  J. Bol,et al.  Plant Pathogenesis-Related Proteins Induced by Virus Infection , 1990 .

[71]  L. C. Loon,et al.  Protease activity and pathogenesis-related proteins in virus-infected Samsun NN tobacco leaves , 1989 .

[72]  R. Moss,et al.  Primary structure and properties of helothermine, a peptide toxin that blocks ryanodine receptors. , 1995, Biophysical journal.

[73]  W. Peacock,et al.  Chitinase, beta-1,3-glucanase, osmotin, and extensin are expressed in tobacco explants during flower formation. , 1990, The Plant cell.

[74]  A. Granell,et al.  Induction of pathogenesis-related proteins in tomato by citrus exocortis viroid, silver ion and ethephon , 1987 .

[75]  A. Stintzi,et al.  Substrate specificities of tobacco chitinases. , 1998, The Plant journal : for cell and molecular biology.

[76]  M. Legrand,et al.  Biological function of pathogenesis-related proteins: Four tobacco pathogenesis-related proteins are chitinases. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[77]  H. Linthorst,et al.  Pr-1: A Group of Plant Proteins Induced Upon Pathogen Infection , 1999 .

[78]  B. Martin,et al.  Isolation and characterization of helothermine, a novel toxin from Heloderma horridum horridum (Mexican beaded lizard) venom. , 1990, Toxicon : official journal of the International Society on Toxinology.

[79]  G. Lipowsky,et al.  CRISP-3, a protein with homology to plant defense proteins, is expressed in mouse B cells under the control of Oct2 , 1996, Molecular and cellular biology.

[80]  K. Wüthrich,et al.  NMR solution structure of the pathogenesis-related protein P14a. , 1997, Journal of molecular biology.

[81]  W. K. Roberts,et al.  A new family of plant antifungal proteins. , 1991, Molecular plant-microbe interactions : MPMI.