Expression of a cucumber class III chitinase and <Emphasis Type="Italic">Nicotiana plumbaginifolia</Emphasis>class I glucanase genes in transgenic potato plants

The genes encoding for a cucumber class III chitinase and Nicotiana plumbaginifolia class I glucanase were co-introduced into Slovak potato (Solanum tuberosum L.) breeding line 116/86 using Agrobacterium tumefaciens. For both transgenes the number of integrated copies and level of RNA expression were determined. These analyses demonstrated low variation and significant correlation in expression of the introduced transgenes. The effect of transgene expression on fungal susceptibility of transformants was evaluated in vitro. Hyphal extension assays revealed no obvious differences in the ability of extracts from transformants to inhibit growth of Rhizoctonia solani comparing to non-transformed potato.     

Effect of chitinase antisense RNA expression on disease susceptibility of Arabidopsis plants

Chitinases accumulate in higher plants upon pathogen attack are capable of hydrolyzing chitin-containing fungal cell walls and are thus implicated as part of the plant defense response to fungal pathogens. To evaluate the relative role of the predominate chitinase (class I, basic enzyme) of Arabidopsis thaliana in disease resistance, transgenic Arabidopsis plants were generated that expressed antisense RNA to the class I chitinase. Young plants or young leaves of some plants expressing antisense RNA had <10% of the chitinase levels of control plants. In the oldest leaves of these antisense plants, chitinase levels rose to 37–90% of the chitinase levels relative to vector control plants, most likely because of accumulation and storage of the enzyme in vacuoles. The rate of infection by the fungal pathogen Botrytis cinerea was measured in detached leaves containing 7–15% of the chitinase levels of control plants prior to inoculation. Antisense RNA was not effective in suppressing induced chitinase expression upon infection as chitinase levels increased in antisense leaves to 47% of levels in control leaves within 24 hours after inoculation. Leaves from antisense plants became diseased at a slightly faster rate than leaves from control plants, but differences were not significant due to high variability. Although the tendency to increased susceptibility in antisense plants suggests that chitinases may slow the growth of invading fungal pathogens, the overall contribution of chitinase to the inducible defense reponses in Arabidopsis remains unclear.     

Regulated inactivation of homologous gene expression in transgenic Nicotiana sylvestris plants containing a defense-related tobacco chitinase gene.

Summary The class I chitinases are vacuolar proteins implicated in the defense of plants against pathogens. Leaves of transgenic Nicotiana sylvestris plants homozygous for a chimeric tobacco (Nicotiana tabacum) chitinase gene with Cauliflower Mosaic Virus (CaMV) 35S RNA expression signals usually accumulate high levels of chitinase relative to comparable leaves of non-transformed plants. Unexpectedly, some transgenic plants accumulated lower levels of chitinase than nontransformed plants. We call this phenomenon silencing. The incidence of silencing depends on the early rearing conditions of the plants. When grown to maturity in a greenhouse, 25% of plants raised as seedlings in closed culture vessels were of the silent type; none of the plants raised from seed in a greenhouse showed this phenotype. Silencing is also developmentally regulated. Plants showed three patterns of chitinase expression: uniformly high levels of expression in different leaves, uniformly low levels of expression in different leaves, and position-dependent silencing in which expression was uniform within individual leaves but varied in different leaves on the same plant. Heritability of the silent phenotype was examined in plants homozygous for the transgene. Some direct descendants exhibited a high-silent-high sequence of activity phenotypes in successive sexual generations, which cannot be explained by simple Mendelian inheritance. Taken together, the results indicate that silencing results from stable but potentially reversible states of gene expression that are not meiotically transmitted. Gene-specific measurements of chitinase and chitinase mRNA showed that silencing results from co-suppression, i.e. the inactivation of both host and transgene expression in trans. The silent state was not correlated with cytosine methylation of the transgene at the five restriction sites investigated.These authors have both made an equal contribution to this work     

Molecular cloning and characterization of a pea chitinase gene expressed in response to wounding,fungal infection and the elicitor chitosan

The fungicidal class I endochitinases (E.C.3.3.1.14, chitinase) are associated with the biochemical defense of plants against potential pathogens. We isolated and sequenced a genomic clone, DAH53, corresponding to a class I basic endochitinase gene in pea, Chil. The predicted amino acid sequence of this chitinase contains a hydrophobic C-terminal domain similar to the vacuole targeting sequences of class I chitinases isolated from other plants. The pea genome contains one gene corresponding to the chitinase DAH53 probe. Chitinase RNA accumulation was observed in pea pods within 2 to 4 h after inoculation with the incompatible fungal strain Fusarium solani f. sp. phaseoli, the compatible strain F. solani f.sp. pisi, or the elicitor chitosan. The RNA accumulation was high in the basal region (lower stem and root) of both fungus challenged and wounded pea seedlings. The sustained high levels of chitinase mRNA expression may contribute to later stages of pea's non-host resistance.     

Expression of bacterial chitinase protein in tobacco leaves using two photosynthetic gene promoters

Summary A bacterial chitinase gene from Serratia marcescens (chiA) was fused to (i) a promoter of the ribulose bisphosphate carboxylase small subunit (rbcS) gene and (ii) two different chlorophyll a/b binding protein (cab) gene promoters from petunia. The resulting constructions were introduced into Agrobacterium Ti plasmid-based plant cell transformation vectors and used to generate multiple independent transgenic tobacco plants. ChiA mRNA and protein levels were measured in these plants. On average, the rbcS/chiA fusion gave rise to threefold more chiA mRNA than either cab/chiA fusion. We investigated the influence of sequences around the translational initiation ATG codon on the level of ChiA protein. The rbcS/chiA and cab/chiA fusions in which the sequence in the vicinity of the translational initiation codon is ACC ATGGC gave rise to transformants with higher levels of ChiA protein than those carrying a cab/chiA fusion with the sequence CAT ATGCG in the same region. This difference in translational efficiency is consistent with previous findings on preferred sequences in this region of the mRNA. In those transformants showing the highest level of ChiA expression, ChiA protein accumulated to about 0.25% of total soluble leaf protein. These plants contained significantly higher chitinase enzymatic activity than control plants.     

Altered expression of an ankyrin-repeat protein results in leaf abnormalities,necrotic lesions,and the elaboration of a systemic signal

Summary The PR-like proteins, class I -1,3-glucanase (GLU I) and chitinase (CHN I), are induced as part of a stereotypic response that can provide protection against viral, bacterial, and fungal pathogens. We have identified two Nicotiana plumbaginifolia ankyrin-repeat proteins, designated lucanohydrolase inding roteins (GBP) 1 and 2, that bind GLU I and CHN I both in vitro and when expressed in yeast cells. Sense as well as antisense transformants of tobacco carrying the GBP1 gene elaborated graft-transmissible acropetally moving signals that induced the downward curling of young leaves. This phenotype was associated with reduced starch, sucrose, and fructose accumulation; the formation of necrotic lesions; and, the induction of markers for the hypersensitive response. GBP1/2 are members of a conserved lant-specific yrin- repeat (PANK) family that includes proteins implicated in carbohydrate allocation, reactive oxygen metabolism, hypersensitive cell death, rapid elicitor responses, virus pathogenesis, and auxin signaling. The similarity in phenotype of PANK transformants and transformants altered in carbohydrate metabolism leads us to propose that PANK family members are multifunctional proteins involved in linking plant defense responses and carbohydrate metabolism.     

Plant selectable markers and reporter genes

In recent years, considerable progress has been made in genetic engineering of various plant species, both agronomically important crops as well as model plants. The bases of this progress were, in addition to efficient transformation methods, the design of appropriate signals regulating transgene expression and the use of selection marker or reporter genes. In most cases, a gene of interest is introduced into plants in association with a selectable marker gene (nptII, hpt, acc3, aadA, bar, pat). Recovery of a transgenic plant is, therefore, facilitated by selection of putative transformants on a medium containing a selection agent, such as antibiotic (nptII, hpt, acc3, aadA), antimetabolite (dhfr), herbicide (bar, pat), etc. On the other hand, use of reporter genes (cat, lacZ, uidA, luc, gfp) allows not only to distinguish transformed and non-transformed plants, but first of all to study regulation of different cellular processes. In particular, by employing vital markers (Luc, GFP) gene expression, protein localization and intracellular protein traffic can be now observed in situ, without the need of destroying plant.