Auxin binding protein: curiouser and curiouser.

Auxin is implicated in a variety of plant developmental processes, yet the molecular mechanism of auxin response remains largely unknown. Auxin binding protein 1 (ABP1) mediates cell expansion and might be involved in cell cycle control. Structural modeling shows that it is a beta-barrel dimer, with the C terminus free to interact with other proteins. We do not know where ABP1 performs its receptor function. Most ABP1 is detected within the endoplasmic reticulum but the evidence indicates that it functions at the plasma membrane. ABP1 is established as a crucial component of auxin signaling, but its precise mechanism remains unclear.

AXR2 encodes a member of the Aux/IAA protein family.

The dominant gain-of-function axr2-1 mutation of Arabidopsis causes agravitropic root and shoot growth, a short hypocotyl and stem, and auxin-resistant root growth. We have cloned the AXR2 gene using a map-based approach, and find that it is the same as IAA7, a member of the IAA (indole-3-acetic acid) family of auxin-inducible genes. The axr2-1 mutation changes a single amino acid in conserved domain II of AXR2/IAA7. We isolated loss-of-function mutations in AXR2/IAA7 as intragenic suppressors of axr2-1 or in a screen for insertion mutations in IAA genes. A null mutant has a slightly longer hypocotyl than wild-type plants, indicating that AXR2/IAA7 controls development in light-grown seedlings, perhaps in concert with other gene products. Dark-grown axr2-1 mutant plants have short hypocotyls and make leaves, suggesting that activation of AXR2/IAA7 is sufficient to induce morphological responses normally elicited by light. Previously described semidominant mutations in two other Arabidopsis IAA genes cause some of the same phenotypes as axr2-1, but also cause distinct phenotypes. These results illustrate functional differences among members of the Arabidopsis IAA gene family.

The ubiquitin-related protein RUB1 and auxin response in Arabidopsis.

The AXR1 (auxin-resistant) protein, which has features of the ubiquitin-activating enzyme E1, is required for normal response to the plant hormone auxin in Arabidopsis thaliana. ECR1 functions together with AXR1 to activate members of the RUB/NEDD8 family of ubiquitin-related proteins. Extracts from mutant seedlings lacking AXR1 did not promote formation of the RUB-ECR1 thiolester, indicating that AXR1 is the major activity in this tissue. AXR1 was localized primarily to the nucleus of dividing and elongating cells, suggesting that the targets of RUB modification are nuclear. These results indicate that auxin response depends on RUB modification of one or more nuclear proteins.

The complete cDNA sequence and structural polymorphism of the polypeptide chain of porcine submaxillary mucin.

The complete structure of the DNA encoding the polypeptide chain of porcine submaxillary mucin has been determined. The polypeptide is composed of distinct domains. A large central domain containing tandem repeats of 81 residues each is flanked by much shorter domains with sequences similar to the tandem repeats. Four disulfide-rich domains, three at the amino terminus and one at the carboxyl terminus, complete the chain. The disulfide-rich domains have significant sequence identity to those of other mucins and prepro-von Willebrand factor. The coding region of the mucin gene is highly polymorphic, and three alleles were identified in a single animal that encoded different numbers of the 81-residue tandem repeats. A single large exon devoid of introns encodes the tandem repeat domains. The largest allele with 135 tandem repeats encoded 13,288 amino acids to give a polypeptide with Mr = 1,184,106. The other two alleles contained 99 and 125 tandem repeats, respectively. Each allele also showed different restriction fragment length polymorphisms, which is consistent with the different patterns seen in individual animals. Fragment length polymorphism was also seen within two different families of animals, indicating that the polymorphism observed occurs in a single generation.

The AXR1 and AUX1 genes of Arabidopsis function in separate auxin-response pathways.

The recessive mutations aux1 and axr1 of Arabidopsis confer resistance to the plant hormone auxin. The axr1 mutants display a variety of morphological defects. In contrast, the only morphological defect observed in aux1 mutants is a loss of root gravitropism. To learn more about the function of these genes in auxin response, the expression of the auxin-regulated gene SAUR-AC1 in mutant and wild-type plants has been examined. It has been found that axr1 plants display a pronounced deficiency in auxin-induced accumulation of SAUR-AC1 mRNA in seedlings as well as rosette leaves and mature roots. In contrast, the aux1 mutation has a modest effect on auxin induction of SAUR-AC1. To determine if the AUX1 and AXR1 genes interact to facilitate auxin response, plants which are homozygous for both aux1 and axr1 mutations have been constructed and characterized. The two mutations are additive in their effects on auxin response, suggesting that each mutation confers resistance by a different mechanism. However, the morphology of double mutant plants indicates that there is an inter-action between the AXR1 and AUX1 genes. In mature plants, the aux1-7 mutation acts to partially suppress the morphological defects conferred by the axr1-12 mutation. This suppression is not accompanied by an increase in auxin response, as measured by SAUR-AC1 expression, suggesting that the interaction between the AUX1 and AXR1 genes is indirect.

The axr2-1 mutation of Arabidopsis thaliana is a gain-of-function mutation that disrupts an early step in auxin response.

The dominant axr2-1 mutation of Arabidopsis thaliana confers resistance to the plant hormones auxin, ethylene, and abscisic acid. In addition, axr2-1 has pleiotropic effects on plant morphology which include gravitropic defects in roots, hypocotyls and inflorescences of axr2-1 plants. Two genetic screens were conducted to isolate new mutations at the AXR2 locus. First, axr2-1 pollen was gamma-irradiated, crossed onto wild-type plants, and the M1 progeny screened for loss of the axr2-1 phenotype. Large deletions of the axr2-1 region on chromosome 3 resulted; however, none of these deletions appeared to be heritable. In the second, M2 seed obtained from axr2-1 gl-1 plants was screened for reversion of the axr2-1 phenotype. One revertant line, axr2-r3, has a distinctive phenotype caused by a second mutation at the axr2 locus. To learn more about the nature of the axr2-1 mutation, the effects of varying the ratio of wild-type to mutant copies of the AXR2 gene were examined by comparing plants of the following genotypes: +/+, +/+/+, axr2-1/axr2-1, axr2-1/+ and axr2-1/+/+. Additionally, accumulation of transcripts from the auxin-inducible SAUR-AC1 gene was examined to determine the response of wild-type and mutant plants to auxin. Wild-type seedlings and mature plants accumulate transcripts with auxin treatment. In contrast, axr2-1 tissue does not accumulate SAUR-AC1 transcripts in response to auxin. Taken together, these results indicate that axr2-1 is a neomorphic or hypermorphic mutation that disrupts an early step in an auxin response pathway.

Arabidopsis auxin-resistance gene AXR1 encodes a protein related to ubiquitin-activating enzyme E1.

The plant hormone auxin has a central role in many aspects of plant growth and development. By screening for mutants of Arabidopsis that are resistant to exogenous auxin, we have identified several genes that are required for normal auxin response. One of these genes, AXR1, is defined by recessive mutations that confer auxin resistance to the roots, rosettes and inflorescences of mutant plants. In addition, axr1 mutants display a variety of morphological defects that are consistent with a reduction in auxin sensitivity. Here we isolate the AXR1 gene using a map-based approach and report that AXR1 encodes a new protein with significant sequence similarity to the ubiquitin-activating enzyme E1. The AXR1 protein is highly diverged from previously characterized E1 enzymes, however, and lacks a key cysteine residue that is essential for E1 activity. AXR1 may therefore define a new class of enzymes in the ubiquitin pathway or it may have a novel function in cellular regulation which is unrelated to ubiquitin conjugation.

Effects of the axr2 mutation of Arabidopsis on cell shape in hypocotyl and inflorescence.

The axr2 mutation of Arabidopsis thaliana (L.) Heynh. confers resistance to the plant growth hormones auxin, ethylene and abscisic acid. In addition, mutant plants have a pronounced dwarf phenotype and display defects in both shoot and root gravitopism. To further characterize this mutant we have determined the phenotype of both dark- and light-grown mutant seedlings. We find that the height of axr2 hypocotyls is reduced in dark conditions compared with wild-type seedlings and that both dark- and light-grown hypocotyls have a gravitropic defect. In addition, we have examined the cellular anatomy of a variety of wild-type and axr2 tissues using light and scanning electron microscopy. Our results indicate that the axr2 mutation has a dramatic effect on cell length in both the inflorescence and the hypocotyl and a lesser effect on cell number in these tissues. The largest difference was observed in the epidermis of the inflorescence where axr2 cells were approximately eightfold shorter than wild-type cells. We suggest that these reductions in cell length and number are sufficient to explain most aspects of the axr2 phenotype. In addition, we propose that a reduction in auxin-mediated cell elongation is responsible for the gravitropic defect in mutant roots, hypocotyls and floral stems. Finally, we have found that the reduction in epidermal cell size in the mutant inflorescence is accompanied by a fourfold increase in stoma density. The implications of this result for models of stoma development are discussed.

Porcine submaxillary mucin contains a cystine-rich, carboxyl-terminal domain in addition to a highly repetitive, glycosylated domain.

The sequence of a 3.65-kilobase cDNA encoding a large portion of the polypeptide chain of porcine submaxillary mucin (apomucin) has been completed. The encoded polypeptide contains 1150 residues with the carboxyl-terminal 240 residues forming a globular domain that is rich in half-cystine, but deficient in sites for oligosaccharide attachment. The remaining 910 residues preceding the half-cystine-rich domain appear devoid of secondary structures, but they are rich in serine and threonine to which the O-linked oligosaccharides are bound. The first 391 residues of apomucin contain several tandemly repeated, identical sequences of 81 residues. Blots of genomic DNA partially digested with restriction nucleases show that at least 25 of these identical repeats are present in apomucin. The amino acid composition of apomucin isolated in the absence of protease inhibitors was shown earlier (Eckhardt, A. E., Timpte, C. S., Abernethy, J. L., Toumadje, A., Johnson, W. C., Jr., and Hill, R. L. (1987) J. Biol. Chem. 282, 11339-11344) to be devoid of half-cystine. In contrast, the amino acid composition of mucin purified in the presence of protease inhibitors contains half-cystine in amounts predicted by the cDNA sequence and also suggests that this mucin has about 25 tandem repeats. Thus, apomucin contains at least 2800 amino acid residues. Moreover, immunoblots of apomucin prepared in the presence or the absence of protease inhibitors, with antibodies specific for the half-cystine-rich domains or the tandem repeat sequences, show that the half-cystine-rich domain is absent in apomucin unless protease inhibitors are present throughout. Both types of mucin, however, contain the highly repetitive sequences. The molecular weight of undegraded apomucin has not been established exactly, but gel filtration in 6 M guanidine hydrochloride suggests that it is considerably higher than 250,000. RNA blot analysis shows that apomucin mRNA is large and polydisperse in accord with the message size necessary to synthesize the large apomucin polypeptide. These structural features of apomucin suggest a model for the structure of the mucin molecule that correlates well with its reported properties.

Porcine submaxillary gland apomucin contains tandemly repeated, identical sequences of 81 residues.

A lambda gt11 cDNA library, prepared from porcine submaxillary gland mRNA, was screened with anti-apomucin IgG, and five antibody-reactive phage were isolated. The phage with the largest cDNA insert, designated lambda PSM103, was further characterized. Its fusion protein reacted with anti-apomucin IgG and was used to affinity purify antibodies that specifically reacted with apomucin, indicating that the protein shares antigenic determinants with apomucin. The nucleotide sequence of 1510 bases in the 3.7-kilobase cDNA insert of lambda PSM103 has been established, thereby giving a deduced amino acid sequence of 503 residues in apomucin, or about 45% of the molecule. The deduced sequence of the apomucin polypeptide was found to contain 4.8 tandemly repeated, identical sequences of 81 residues each. The presence of these uniquely repeated sequences was confirmed by restriction endonuclease digestion of DNA derived from lambda PSM103. The repeat sequence was also confirmed in apomucin by the isolation of an 81-residue tryptic peptide with an amino acid composition and an amino-terminal amino acid sequence (up to 44 residues) identical to those of the tandem repeat. Moreover, the peptide was isolated in 760% yield, indicating that the tandem repeat occurs at least eight times in apomucin. The presence of such a long repetitive region in the gene for apomucin raises the possibility for considerable polymorphism in the gene and a corresponding size heterogeneity of apomucin. The predicted secondary structure of the 503 residues confirms the earlier proposal that apomucin is an extended, nonglobular polypeptide. Although the sequences around 192 serine and threonine residues have been established in apomucin, a recognition sequence for the N-acetylgalactosaminyltransferase that initiates glycosylation of apomucin is not evident, except that the glycosylated residues occur in turns.

Structural properties of porcine submaxillary gland apomucin.

Porcine submaxillary gland mucin was deglycosylated with a mixture of pure glycosidases to give apomucin containing less than 1% carbohydrate. The resulting apomucin freed of glycosidases was found to contain nine amino acids: threonine, serine, glutamic acid, proline, glycine, alanine, valine, isoleucine, and arginine. Serine, threonine, glycine, and alanine comprise 77% of the composition. The molecular weight of apomucin was 96,500 as determined by gel filtration in guanidine hydrochloride. Its Stokes radius was greater than 68.6 A, a far larger value than expected for a globular protein with Mr = 96,500. Circular dichroism spectroscopy of apomucin suggests that it contains 42% aperiodic or "other" structure, 40% beta-turns, 10% antiparallel pleated sheet, and 8% helical structures. The predicted secondary structure of a 50-residue peptide from ovine submaxillary gland mucin resembles the circular dichroism predictions, being dominated by turns that would lead to an extended nonglobular structure. Analysis for the secondary structure of a 36-residue tryptic peptide derived from porcine submaxillary gland apomucin predicts a similar structure. It is concluded that apomucin is likely devoid of traditional secondary structure and serves as a scaffold upon which oligosaccharides are added in O-glycosidic linkage. When sufficient sialic acid is present in the oligosaccharides, native highly viscous mucin containing about two-thirds carbohydrate by weight is obtained.