Plant Physiol. (1998) 117: 1325-1332

Expressed Sequence Tags from a Root-Hair-Enriched Medicago truncatula cDNA Library¹

Peter A. Covitz², Lucinda S. Smith, and Sharon R. Long^*

Department of Biological Sciences (P.A.C., L.S.S., S.R.L.), and Howard Hughes Medical Institute (L.S.S., S.R.L.), Stanford University, Stanford, California 94305-5020

	ABSTRACT

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The root hair is a specialized cell type involved in water and nutrient uptake in plants. In legumes the root hair is also the primary site of recognition and infection by symbiotic nitrogen-fixing Rhizobium bacteria. We have studied the root hairs of Medicago truncatula, which is emerging as an increasingly important model legume for studies of symbiotic nodulation. However, only 27 genes from M. truncatula were represented in GenBank/EMBL as of October, 1997. We report here the construction of a root-hair-enriched cDNA library and single-pass sequencing of randomly selected clones. Expressed sequence tags (899 total, 603 of which have homology to known genes) were generated and made available on the Internet. We believe that the database and the associated DNA materials will provide a useful resource to the community of scientists studying the biology of roots, root tips, root hairs, and nodulation.

	INTRODUCTION

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Roots provide structural and physiological support for plant interactions with the soil environment. Epidermal root hairs are specialized cells with a high surface-to-volume ratio that enables them to perform an important role in transport of water, ions, and nutrients. Root hairs are outgrowths of trichoblasts, and elongate by tip growth, a distinct mode of plant cell growth shared only by pollen tubes (Peterson and Farquhar, 1996). The patterning, differentiation, and growth of root hairs has been elucidated by genetic and cell biological studies (Di Cristina et al., 1996; Galway et al., 1997; Sanchez-Fernandez et al., 1997; Schneider et al., 1997), but many aspects of root-hair cell function remain unknown. In the Fabaceae, root hairs are also significant in having active responses to Rhizobium and related bacteria during the early stages of the symbiosis that leads to nitrogen fixation (Brewin, 1991; Hirsch, 1992). The identification of root proteins important for transport, cell growth and differentiation, and interaction with microbes is therefore of interest for studies in numerous plant species. However, because root hairs are small and often transient structures, direct biochemical analysis is challenging.

Medicago truncatula has emerged as an important experimental plant species both for studying nodulation by Rhizobium and for investigating mycorrhizal associations. M. truncatula is nodulated by R. meliloti, a bacterial species well characterized with respect to genetics and biochemistry. M. truncatula is autogamous and has a relatively small diploid genome and a number of genetically distinguishable ecotypes. These properties contribute to its suitability for molecular genetic analyses (Barker et al., 1990; Blondon et al., 1994; Cook et al., 1997). Genetic screens for plants with altered symbiotic phenotypes and various molecular approaches have identified several interesting mutations and genes (Benaben et al., 1995; Cook et al., 1995; Sagan et al., 1995; Gamas et al., 1996; Harrison, 1996; Peng et al., 1996; Burleigh and Harrison, 1997; Penmetsa and Cook, 1997).

Single-pass sequencing of cDNAs randomly picked from a library of genes made from a tissue of interest offers a complementary approach to biochemical and genetic analysis (Adams et al., 1991). ESTs generated by such an effort are compared with databases of identified genes. The results of these comparisons are used as a guide to assign putative identifications to the cDNAs. Researchers may then search or browse through the putative identifications of the ESTs to determine which genes may be of interest for further study. An investigator can also compare an experimentally obtained partial protein or nucleic acid sequence with the EST database to find out whether the cDNA for the gene has already been cloned. These methods have led to the rapid identification of genes in a number of organisms and have accelerated research by providing genetic material for further investigation (Adams et al., 1991, 1993; McCombie et al., 1992; Okubo et al., 1992; Newman et al., 1994; Rounsley et al., 1996).

In this paper we describe the collection of ESTs from a root-hair-enriched root-tip cDNA library from M. truncatula. We have constructed a website for access to the resulting database of 899 sequences. The sequence information and clones resulting from this effort may provide a useful tool for researchers studying general root physiology and molecular biology, and should have particular applications to the molecular biology of the R. meliloti-M. truncatula symbiosis.

	MATERIALS AND METHODS

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Tissue Collection

Seedlings were placed on a sterile, wet paper towel with roots dangling 2 to 3 cm over one long edge, and the towel was rolled. The exposed root tips were dipped in liquid nitrogen and broken off. In one preparation these root tips with intact root hairs were used directly for RNA isolation. In another preparation root hairs were isolated by stirring in liquid nitrogen on a magnetic stir plate for 15 to 30 min until they broke off. Stripped root tips fell to the bottom of the container, whereas detached root hairs floated and were collected by decanting the liquid nitrogen (Rohm and Werner, 1987).

RNA Isolation

cDNA Library Construction

Sequencing

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Template purification and sequencing of the plasmid cDNAs was performed either by the authors or by commercial DNA sequencing service providers (e.g. Bio-101 [Vista, CA] and Lark Technologies [Houston, TX]). All sequencing reactions contained the standard T3 sequencing primer, and thus read into the presumed 5 end of each cDNA. Reactions were run and analyzed on either capillary or slab-gel electrophoresis automated sequencing machines (Perkin-Elmer). These machines generate two computer files for each sequencing run: a chromatogram file and a plain text file.

Sequence Editing

Homology Comparisons and Database Construction

	RESULTS

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Single-Pass Sequencing of Random cDNAs

We constructed the library by unidirectional insertion of oligo-dT-primed cDNAs into -ZAP-Express. The phage library was converted through mass excision to a plasmid library in the vector pBK-CMV. Individual clones from the plasmid library were picked at random and sequenced using a standard T3 primer that was annealed and extended into the 5 side of the inserted cDNA. Of 958 sequencing reactions attempted, 919 produced some length of readable sequence.

The text file resulting from each sequencing reaction was edited using both automated and, if necessary, manual methods. SeqTrim was used to remove leading vector and trailing, poor-quality sequences from each file. In cases in which the sequencing reaction extended past the poly(A⁺) tail of the gene, the sequence was trimmed to remove the 3 vector and linker sequences. SeqTrim also flagged sequences derived from anomalous clones. These anomalies generally fell into three classes: (a) clones with altered adaptor sequence or incorrect base calls at the junction between the vector and the cDNA insert; (b) clones with inserts in the reverse orientation; or (c) clones without inserts altogether. The files for these three classes were edited manually; sequences from the third class were removed from further consideration.

Putative Identification of Genes

Of the 899 ESTs, 603 had significant homology to previously identified genes. Although the BLAST scores and P values were considered, the assessment of whether a given homology was significant was determined by investigator judgment, not by absolute numerical cutoffs. The annotations of genes with similarities to an EST were used to assign a putative identification to that EST. In cases in which the annotation was vague, information contained in MEDLINE abstracts related to the gene was used to assign a putative identification. The 603 ESTs with similarity to known genes represent 356 distinct genes, as indicated by their putative identifications. These distinct identifications were grouped into 13 functional categories, which are listed in Table II.

Abundantly Expressed Genes

Met synthase is also related to ethylene metabolism, so the abundance of the gene is intriguing because of the possibly complex role(s) of ethylene in root-hair development and symbiosis (Masucci and Schiefelbein, 1996; Dolan, 1997; Heidstra et al., 1997; Penmetsa and Cook, 1997). However, the presence of the ethylene-response inhibitor Ag₂SO₄ in the plant growth medium (see ``Materials and Methods'') may have perturbed the expression of enzymes involved in ethylene metabolism. This possibility was not specifically tested in M. truncatula roots.

	DISCUSSION

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Genes of Interest

Genes categorized under defense and secondary metabolism functions should also be appropriate targets of study given the possible involvement, or suppression, of host defenses during infection by Rhizobium (Hirsch and Fang, 1994; Mellor and Collinge, 1995; Spaink, 1995). In particular, an endochitinase homolog may be intriguing to examine (EST 00194; serial nos. can be used to obtain detailed EST information at http://bio-SRL8.stanford.edu, as described below). This endochitinase EST does not have significant homology to a previously identified M. truncatula chitinase cDNA derived from roots infected with R. meliloti (accession no. Y10373; A. Niebel, unpublished data). The identification of two different chitinases in uninfected and infected roots permits more rigorous testing of the hypothesis that chitinases have a regulatory role in plant responses to lipooligosaccharide nodulation factors (Staehelin et al., 1994).

Several other sequences are especially interesting given their homology to genes with known functions in other systems. One intriguing sequence in the collection is a homolog of the mammalian eyes absent (eya) gene (EST 00777). The BLAST comparison of the EST with homology to this gene yielded high scoring pairs spanning 103 amino acids of human eya2. The P value of the match was 4.9e¹⁴, suggesting that the alignment was not due to chance. The eya genes have been implicated in eye development in both mammals and insects, a finding that has challenged the long-held notion that eyes evolved independently in these two branches of animal phylogeny (Duncan et al., 1997; Zimmerman et al., 1997). The presence of an eya homolog in plants suggests that the history of this gene family may extend to a common ancestor of plants and animals.

Another sequence of particular significance is a His kinase (EST 00711) with the strongest similarity to a bacterial two-component regulator (P < 1.1e²⁶). Only a few His kinase sequences have been reported in plants, but these are of high interest because one, the ETR1 gene, has been identified by genetics as an ethylene receptor, and its product has been shown by direct biochemical studies to be an ethylene-binding protein (Chang et al., 1993; Schaller and Bleecker, 1995). Another sequence with His kinase homology is implicated by genetic tests as a possible cytokinin receptor (Kakimoto, 1996). Thus, the functionally characterized His kinase-like sequences reported in plants are possible receptors for chemical ligands. The appearance of a new His kinase in the root-hair-enriched library is important in light of the internal and external chemical signals that are operating in roots and their root hairs. The M. truncalata sequence appears to be distinct from ETR1 and other functionally characterized genes. We are pursuing such characterization of this newly identified His kinase homolog through construction of antisense and other transgenic plants.

We expected to find expressed sequences representing major root functions such as transport and cell growth and division; however, since no cells from other portions of the plant were present, we did not expect to find functions typically associated with shoot, leaf, or reproductive organs. Therefore, some EST sequences in the library are developmentally surprising. These include chlorophyll a- and b-binding protein (ESTs 00122, 00414, and 00460), an embryo-specific protein (EST 00339), and a pollen-specific protein (EST 00010).

Several genes with homology to sugar transporters were found. No homologs of the nitrate transporter or of other putative plasmalemma transporters were identified. The apparent paucity of transporter genes is somewhat puzzling. However, we note that more than one-fifth of the ESTs in the database show no significant homology to known genes. Transporter genes may be represented among these unclassified sequences. It is also possible that the putative identifications of the membrane transporters in Table II reflect their basic membrane transport functions, but do not necessarily identify the correct substrate.

Sequence similarity as indicated by BLAST does not always reflect actual conservation at the relevant functional sites of the proteins in question. Examination of individual sequence lineups and reference to all original papers should precede conclusions about the likely function of any particular expressed gene. The Web site described below is designed to facilitate this process.

Internet Access to Detailed EST Information

Uses for the ESTs

Root hairs are mechanically and optically accessible and their growth can be actively studied using a number of cell biological techniques and experimental manipulations (Dazzo et al., 1996; Ehrhardt et al., 1996; Galway et al., 1997). EST sequences that encode proteins of known or predicted function may be used to create peptide antigens for generating antibodies to be used in such studies. The protein products of cytoskeletal protein and cell wall enzyme genes may be good candidates for this approach.

Finally, the EST database may be of use to scientists who have biochemically purified proteins of interest from M. truncatula. The partial peptide sequence of a purified protein could be compared against translated EST sequences. If present, related and more extensive cDNAs could then be readily identified and used as tools for additional studies.

	FOOTNOTES

   Received December 30, 1997; accepted May 4, 1998.

	ABBREVIATIONS

Abbreviations: EST, expressed sequence tag.

	ACKNOWLEDGMENTS

We are grateful to Audrey Southwick for assistance in the preparation of plants and isolation of RNA for the construction of the library and to Melanie Ukanwa for assisting with the BLAST homology searches. We thank Michael Cherry and David Flanders for their advice on constructing the EST database, JoAnne Connelly for assistance with the manuscript, and members of our laboratory for numerous useful suggestions.

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