Plinio Guzmán

ETHYLENE-INSENSITIVE5 encodes a 5′→3′ exoribonuclease required for regulation of the EIN3-targeting F-box proteins EBF1/2

Ethylene is a gaseous plant growth regulator that controls a multitude of developmental and stress responses. Recently, the levels of Arabidopsis EIN3 protein, a key transcription factor mediating ethylene-regulated gene expression, have been demonstrated to increase in response to the presence of ethylene gas. Furthermore, in the absence of ethylene, EIN3 is quickly degraded through a ubiquitin/proteasome pathway mediated by two F-box proteins, EBF1 and EBF2. Here we report the identification of ETHYLENE-INSENSITIVE5 as the 5′→3′ exoribonuclease XRN4. Specifically, we demonstrate that EIN5 is a component of the ethylene signal transduction cascade acting downstream of CTR1 that is required for ethylene-mediated gene expression changes. Furthermore, we find that the ethylene insensitivity of ein5 mutant plants is a consequence of the over-accumulation of EBF1 and EBF2 mRNAs resulting in the under-accumulation of EIN3 even in the presence of ethylene gas. Together, our results suggest that the role of EIN5 in ethylene perception is to antagonize the negative feedback regulation on EIN3 by promoting EBF1 and EBF2 mRNA decay, which consequently allows the accumulation of EIN3 protein to trigger the ethylene response.

Early elicitor induction in members of a novel multigene family coding for highly related RING-H2 proteins in Arabidopsis thaliana.

We describe the identification and structural characterization of a novel family of Arabidopsis genes related to ATL2 which encode a variant of the RING zinc finger domain, known as RING-H2. Analysis of genes selected by us and of sequences from Arabidopsis stored in databases permitted the prediction of several RING-H2 proteins that contain highly homologous RING domains. The ATL gene family is represented by fifteen sequences that contain, in addition to the RING, a transmembrane domain which is located in most of them towards the N-terminal end. Transgenic Arabidopsis seedlings carrying the ATL2 promoter fused to the GUS reporter gene revealed that the expression of ATL2 is rapidly induced after exposure to chitin or inactivated crude cellulase preparations. Rapid induction of transcript accumulation of another member of the ATL family was also observed under the same conditions. These results suggest that some ATLs may be involved in the early stages of the defense response triggered in plants in response to pathogen attack.

Gene isolation in Arabidopsis thaliana by conditional overexpression of cDNAs toxic to Saccharomyces cerevisiae: identification of a novel early response zinc-finger gene.

In an effort to identify novel regulatory plant genes, conditional overexpression of toxicArabidopsis thaliana gene products inSaccharomyces cerevisiae was evaluated as a genetic selection scheme. The screening method was tested on a fraction of a cDNA expression library and led to the identification of two Arabidopsis cDNA clones that were toxic to yeast; one corresponded to histone H1 and the other to a previously unidentified gene. This new gene, namedATL2, combines a RING-like zinc-binding motif and a putative signal anchor sequence for membrane insertion in the same molecule. Furthermore, inspection of the 3′ untranslated region reveals two types of sequences which appear to be key determinants in rapid transcript decay. Indeed, rapid and transient accumulation of transcript occurs in the presence of a protein synthesis inhibitor and of the growth regulator auxin. These features provide evidence thatATL2 is an early-response gene. Thus,ATL2 represents one of the first early-response plant genes to be described which possesses a distinct regulatory domain; the fact thatATL2 mRNA is induced by auxin suggests that it might have a role during the response of plants to this growth regulator.

Diversity in the Architecture of ATLs, a Family of Plant Ubiquitin-Ligases, Leads to Recognition and Targeting of Substrates in Different Cellular Environments

Ubiquitin-ligases or E3s are components of the ubiquitin proteasome system (UPS) that coordinate the transfer of ubiquitin to the target protein. A major class of ubiquitin-ligases consists of RING-finger domain proteins that include the substrate recognition sequences in the same polypeptide; these are known as single-subunit RING finger E3s. We are studying a particular family of RING finger E3s, named ATL, that contain a transmembrane domain and the RING-H2 finger domain; none of the member of the family contains any other previously described domain. Although the study of a few members in A. thaliana and O. sativa has been reported, the role of this family in the life cycle of a plant is still vague. To provide tools to advance on the functional analysis of this family we have undertaken a phylogenetic analysis of ATLs in twenty-four plant genomes. ATLs were found in all the 24 plant species analyzed, in numbers ranging from 20–28 in two basal species to 162 in soybean. Analysis of ATLs arrayed in tandem indicates that sets of genes are expanding in a species-specific manner. To get insights into the domain architecture of ATLs we generated 75 pHMM LOGOs from 1815 ATLs, and unraveled potential protein-protein interaction regions by means of yeast two-hybrid assays. Several ATLs were found to interact with DSK2a/ubiquilin through a region at the amino-terminal end, suggesting that this is a widespread interaction that may assist in the mode of action of ATLs; the region was traced to a distinct sequence LOGO. Our analysis provides significant observations on the evolution and expansion of the ATL family in addition to information on the domain structure of this class of ubiquitin-ligases that may be involved in plant adaptation to environmental stress.

Four distinct classes of proteins as interaction partners of the PABC domain of Arabidopsis thaliana Poly(A)-binding proteins.

Poly(A)-binding proteins (PABPs) play an important role in the regulation of translation and the control of mRNA stability in eukaryotes, and their functions are known to be essential in many organisms. PABPs contain a highly conserved C-terminal segment termed the PABC domain. The PABC domain from human PABP interacts with the proteins PAIP1, PAIP2 and RF3 via its PAM2 motifs. These interactions are important for modulating translation. Arabidopsis has eight PABPs, an unexpectedly large number in comparison to other eukaryotes whose genomes have been sequenced. Six of the Arabidopsis PABPs contain the conserved PABC domain. In this work, we have identified PABC-interacting proteins in Arabidopsis. Two proteins, which we named CID1 and CID7, were initially isolated in a two-hybrid screen, and eleven more were predicted to be present in the Arabidopsis proteome and eleven in the rice proteome. Among the 24 PAM2-containing proteins in this set, we observed a diversity of modules of intriguing function, ranging from acidic regions similar to the PAM1 motif found in human PAIP1 and PAIP2, to domains such as the small MutS-related domain, the Lsm domains of Ataxin-2, and RNA recognition motifs (RRMs). We suggest that the large number of PABPs and PAM2-containing proteins may have evolved to provide plants with greater flexibility in modulating the metabolism of specific transcripts. We also found that two PABP genes, PAB2 (ubiquitously expressed) and PAB5 (expressed in reproductive tissues), are essential for viability, suggesting that each has a vital and specific function.

The prolific ATL family of RING-H2 ubiquitin ligases

An abundant class of E3 ubiquitin ligases encodes the RING-finger domain. The RING finger binds to the E2 ubiquitin-conjugating enzyme and brings together both the E2 and substrate. It is predicted that 477 RING finger E3 ligases exist in Arabidopsis thaliana. A particular family among them, named Arabidopsis Tóxicos en Levadura (ATL), consists of 91 members that contain the RING-H2 variation and a hydrophobic domain located at the N-terminal end. Transmembrane E3 ligases are important in several biological processes. For instance, some transmembrane RING finger E3 ligases are main participants in the endoplasmic reticulum-associated degradation pathway that targets misfolded proteins. Functional analysis of a number of ATLs has shown that some of them regulate distinct pathways in plants. Several ATLs have been shown to participate in defense responses, while others play a role in the regulation of the carbon/nitrogen response during post-germinative seedling growth transition, in the regulation of cell death during root development, in endosperm development, or in the transition to flowering under short day conditions. The ATL family has also been instrumental in evolution studies for showing how gene families are expanded in plant genomes.

Genetic interactions of a putative Arabidopsis thaliana ubiquitin-ligase with components of the Saccharomyces cerevisiae ubiquitination machinery.

The feasibility of using the Saccharomyces cerevisiae genetic tools to get insights into the function of a plant-specific ubiquitin-ligase was examined. ATL2 is a potential ubiquitin-ligase of the RING-H2 type that was originally isolated as a conditionally toxic Arabidopsis cDNA when overexpressed in yeast. ATL2 is a member of an Arabidopsis family that comprises 80 proteins. After testing cDNAs from 25 ATL members for toxicity we found that in addition to ATL2 only ATL63 was toxic, suggesting specific interactions of each one of these two ATLs in yeast. We seek to identify suppressors of the ATL2 toxicity in yeast and we found that toxicity was suppressed by knock-out mutations on different components of the ubiquitination pathway. Suppression was achieved in four deubiquitinating enzyme mutants and in one ubiquitin-conjugating enzyme mutant. A model is proposed in which Ubc4 and ATL2 act together to target for degradation one or more essential yeast proteins, Doa4/Ubp4, Ubp6 and Ubp14 have a role in disassembling ubiquitin chains on the target proteins and Ubp15 protects ATL2 from auto-ubiquitination. We presuppose that our approach can be further utilized to analyze the function of this distinctive class of ubiquitin-ligases in yeast as well as in Arabidopsis.

Insights into the evolution and domain structure of Ataxin-2 proteins across eukaryotes.

BackgroundAtaxin-2 is an evolutionarily conserved protein first identified in humans as responsible for spinocerebellar ataxia type 2 (SCA2). The molecular basis of SCA2 is the expansion of a polyglutamine tract in Ataxin-2, encoding a Lsm domain that may bind RNA and a PAM2 motif that enables interaction with the poly (A) binding protein. Although the association with SCA2 has been verified, a detailed molecular function for Ataxin-2 has not been established.ResultsWe have undertaken a survey of Ataxin-2 proteins across all eukaryotic domains. In eukaryotes, except for vertebrates and land plants, a single ortholog was identified. Notably, with the exception of birds, two Ataxin-2 genes exist in vertebrates. Expansion was observed in land plants and a novel class lacking the LsmAD domain was identified. Large polyQ tracts appear limited to primates and insects of the orders Hymenoptera and Diptera. A common feature across Ataxin-2 orthologs is the presence of proline-rich motifs, formerly described in the human protein.ConclusionOur analysis provides valuable information on the evolution and domain structure of Ataxin-2 proteins. Proline-rich motifs that may mediate protein interactions are widespread in Ataxin-2 proteins, but expansion of polyglutamine tracts associated with spinocerebellar ataxia type 2, is present only in primates, as well as some insects. Our analysis of Ataxin-2 proteins provides also a source to examine orthologs in a number of different species.

Detection of genetic variation in Ustilago maydis strains by probes derived from telomeric sequences

Genetic variation using probes derived from telomeric sequences was analysed among several Ustilago maydis strains in an attempt to identify discriminative fingerprint patterns. Three groups of wild isolates from different geographical areas and one group of standard laboratory strains were examined. Analysis of the endmost restriction fragments (EFs) and of the endmost-associated restriction fragments (EAFs) of the chromosomes revealed group differences. Most of the EFs in two groups of strains showed a similar length whereas in the other two groups they were distributed in classes of different lengths. Furthermore, analysis of the EAFs permitted possible fingerprint patterns to be predicted for each group of strains based on the occurrence of amplified bands as well as the presence or absence of distinct bands which were shown to be present in terminal as well as in interstitial sites of the chromosome. The approach evaluated in this work yielded highly polymorphic fingerprint patterns and could be used to distinguish groups of fungal isolates; this approach may also be effective for other fungal systems.

ATLs and BTLs, plant-specific and general eukaryotic structurally-related E3 ubiquitin ligases

Major components of the ubiquitin proteasome system are the enzymes that operate on the transfer of ubiquitin to selected target substrate, known as ubiquitin ligases. The RING finger is a domain that is present in key classes of ubiquitin ligases. This domain coordinates the interaction with a suitable E2 conjugase and the transfer of ubiquitin from the E2 to protein targets. Additional domains coupled to the same polypeptide are important for modulating the function of these ubiquitin ligases. Plants contain several types of E3 ubiquitin ligases that in many cases have expanded as multigene families. Some families are specific to the plant lineage, whereas others may have a common ancestor among plants and other eukaryotic lineages. Arabidopsis Tóxicos en Levadura (ATLs) and BCA2 zinc finger ATLs (BTLs) are two families of ubiquitin ligases that share some common structural features. These are intronless genes that encode a highly related RING finger domain, and yet during evolutionary history, their mode of gene expansion and function is rather different. In each of these two families, the co-occurrence of transmembrane helices or C2/C2 (BZF finger) domains with a selected variation on the RING finger has been subjected to strong selection pressure in order to preserve their unique domain architectures during evolution.