SPATULA and ALCATRAZ, are partially redundant, functionally diverging bHLH genes required for Arabidopsis gynoecium and fruit development

The Arabidopsis gynoecium is a complex organ that facilitates fertilization, later developing into a dehiscent silique that protects seeds until their dispersal. Identifying genes important for development is often hampered by functional redundancy. We report unequal redundancy between two closely related genes, SPATULA (SPT) and ALCATRAZ (ALC), revealing previously unknown developmental roles for each. SPT is known to support septum, style and stigma development in the flower, whereas ALC is involved in dehiscence zone development in the fruit. ALC diverged from a SPT-like ancestor following gene duplication coinciding with the At-β polyploidy event. Here we show that ALC is also involved in early gynoecium development, and SPT in later valve margin generation in the silique. Evidence includes the increased severity of early gynoecium disruption, and of later valve margin defects, in spt-alc double mutants. In addition, a repressive version of SPT (35S:SPT-SRDX) disrupts both structures. Consistent with redundancy, ALC and SPT expression patterns overlap in these tissues, and the ALC promoter carries two atypical E-box elements identical to one in SPT required for valve margin expression. Further, SPT can heterodimerize with ALC, and 35S:SPT can fully complement dehiscence defects in alc mutants, although 35S:ALC can only partly complement spt gynoecium disruptions, perhaps associated with its sequence simplification. Interactions with FRUITFULL and SHATTERPROOF genes differ somewhat between SPT and ALC, reflecting their different specializations. These two genes are apparently undergoing subfunctionalization, with SPT essential for earlier carpel margin tissues, and ALC specializing in later dehiscence zone development.     

Arabidopsis (Brassicaceae) flower development and gynoecium patterning in wild type and Ettin mutants

Screening for mutations that alter flower development in Arabidopsis has led to the identification of two general types of genetic loci: those affecting meristem and organ identity, and those affecting growth and development independent of identity. ettin (ett) mutants belong to the latter class and exhibit pleiotropic phenotypes distinct from previously described Arabidopsis mutants. These phenotypes include increases in sepal and petal number, decreases in stamen number and anther locule number, and gross alteration of tissue patterning in the gynoecium. To determine when and how differences in ett floral meristems originate, flower development was compared between the wild type and ett mutants. ett floral meristems exhibit increases in abaxial sepal and petal primordia number without apparent increases in meristem size. Extra sepal and petal primordia develop into normal organs. In contrast, stamen and carpel primordia exhibit alterations in shape and form, subsequent to premature elongation of the terminal floral meristem. Phenotypes are allele-strength dependent. The stigma develops precociously and style differentiation is basally and abaxially misplaced in ett gynoecia. The data are discussed in the context of a model suggesting that two concentric boundaries specify the apical-basal pattern of gynoecium differentiation.     

The thylakoid protease Deg1 is involved in photosystem‐II assembly in Arabidopsis thaliana

DegP proteases have been shown to possess both chaperone and protease activities. The proteolytic activities of chloroplast DegP‐like proteases have been well documented. However, whether chloroplast Deg proteases also have chaperone activities has remained unknown. Here we show that chloroplast Deg1 also has chaperone activities, like its Escherichia coli ortholog DegP. Transgenic plants with reduced levels of Deg1 accumulated normal levels of different subunits of the major photosynthetic protein complexes, but their levels of photosystem‐II (PSII) dimers and supercomplexes were reduced. In vivo pulse‐chase protein labeling experiments showed that the assembly of newly synthesized proteins into PSII dimers and supercomplexes was impaired, although the synthesis rate of chloroplast proteins was unaffected in the transgenic lines. Protein overlay assays provided direct evidence that Deg1 interacts with the PSII reaction center protein D2. These results suggest that Deg1 assists the assembly of the PSII complex, probably through interaction with the PSII reaction center D2 protein.     

Regulation of MHC class I and II gene transcription: differences and similarities

Major histocompatibility complex (MHC) molecules serve as peptide receptors. These peptides are derived from processed cellular or extra-cellular antigens. The MHC gene complex encodes two major classes of molecules, MHC class I and class II, whose function is to present peptides to CD8⁺ (cytotoxic) and CD4⁺ (helper) T cells, respectively. The genes encoding both classes of MHC molecules seem to originate from a common ancestral gene. One of the hallmarks of the MHC is its extensive polymorphism which displays locus and allele-specific characteristics among the various MHC class I and class II genes. Because of its central role in immunosurveillance and in various disease states, the MHC is one of the best studied genetic systems. This review addresses several aspects of MHC class I and class II gene regulation in human and in particular, the contribution to the constitutive and cytokine-induced expression of MHC class I and II genes of MHC class-specific regulatory elements and regulatory elements which apparently are shared by the promoters of MHC class I and class II genes. Received: 12 January 1998     

Male gametophyte defective 4 encodes a rhamnogalacturonan II xylosyltransferase and is important for growth of pollen tubes and roots in Arabidopsis

In flowering plants, the growth of pollen tubes is essential for the delivery of sperm to the egg cells. Although many factors (including cell‐wall properties) are involved in this process, little is known about the underlying molecular mechanisms that regulate the growth of pollen tubes. We report here the characterization of an Arabidopsis mutant male gametophyte defective 4 (mgp4) that is severely defective in pollen tube growth. The mgp4 mutation also impairs root growth of pollen‐rescued mgp4 mutant plants generated by expressing MGP4 cDNA under the control of a pollen grain/tube‐specific promoter. The MGP4 gene encodes a putative xylosyltransferase and is expressed in many organs/tissues, including pollen tubes and roots. MGP4 protein expressed in Pichia pastoris exhibited xylosyltransferase activity and transferred d ‐xylose onto l ‐fucose. The pectic polysaccharide rhamnogalacturonan II (RG‐II), isolated from 7‐day‐old pollen‐rescued mutant seedlings, exhibited a 30% reduction in 2‐O‐methyl d ‐xylose residues. Furthermore, an exogenous supply of boric acid enhanced RG‐II dimer formation and partially restored the root growth of the pollen‐rescued mutant seedlings. Taken together, these results suggest that MGP4 plays important roles in pollen tube and root growth by acting as a xylosyltransferase involved in the biosynthesis of pectic RG‐II.     

Isolation and characterization of cDNA clones for chicken major histocompatibility complex class II molecules

The chicken major histocompatibility complex (MHC), the B complex, is being intensively analysed at the DNA level. To further probe the molecular structure of chicken MHC class II genes, cDNA clones coding for chicken MHC class II (B-L) p chain molecules were isolated from an inbred G-B2 Leghorn chicken spleen and liver. Twenty-nine cDNA clones were isolated from the spleen and eight cDNA clones were isolated from the liver. Based on restriction maps, most clones could be clustered into one family of genes. Four cDNA clones were sequenced (S7, S10 and S19 from the spleen and L1, which was identical to S19, from the liver). Complete amino acid sequences of B-Lβ chain molecules were predicted from the nucleotide sequences of the cDNA clones. Although both the nature and the location of the conserved residues were similar in chicken and mammalian sequences, some species-specific differences were found, suggesting that the structures of the B-L molecules of this haplotype are similar, but not identical, to their mammalian counterparts.     

The Arabidopsis Tellurite resistance C protein together with ALB3 is involved in photosystem II protein synthesis

Assembly of photosystem II (PSII) occurs sequentially and requires several auxiliary proteins, such as ALB3 (ALBINO3). Here, we describe the role of the Arabidopsis thaliana thylakoid membrane protein Tellurite resistance C (AtTerC) in this process. Knockout of AtTerC was previously shown to be seedling‐lethal. This phenotype was rescued by expressing TerC fused C–terminally to GFP in the terc–1 background, and the resulting terc–1_TerC–GFP line and an artificial miRNA‐based knockdown allele (amiR‐TerC) were used to analyze the TerC function. The alterations in chlorophyll fluorescence and thylakoid ultrastructure observed in amiR‐TerC plants and terc–1_TerC–GFP were attributed to defects in PSII. We show that this phenotype resulted from a reduction in the rate of de novo synthesis of PSII core proteins, but later steps in PSII biogenesis appeared to be less affected. Yeast two‐hybrid assays showed that TerC interacts with PSII proteins. In particular, its interaction with the PSII assembly factor ALB3 has been demonstrated by co‐immunoprecipitation. ALB3 is thought to assist in incorporation of CP43 into PSII via interaction with Low PSII Accumulation2 (LPA2) Low PSII Accumulation3 (LPA3). Homozygous lpa2 mutants expressing amiR‐TerC displayed markedly exacerbated phenotypes, leading to seedling lethality, indicating an additive effect. We propose a model in which TerC, together with ALB3, facilitates de novo synthesis of thylakoid membrane proteins, for instance CP43, at the membrane insertion step.     

The immunophilin-interacting protein AtFIP37 from Arabidopsis is essential for plant development and is involved in trichome endoreduplication

The FKBP12 (FK506-binding protein 12 kD) immunophilin interacts with several protein partners in mammals and is a physiological regulator of the cell cycle. In Arabidopsis, only one specific partner of AtFKBP12, namely AtFIP37 (FKBP12 interacting protein 37 kD), has been identified but its function in plant development is not known. We present here the functional analysis of AtFIP37 in Arabidopsis. Knockout mutants of AtFIP37 show an embryo-lethal phenotype that is caused by a strong delay in endosperm development and embryo arrest. AtFIP37 promoter::beta-glucuronidase reporter gene constructs show that the gene is expressed during embryogenesis and throughout plant development, in undifferentiating cells such as meristem or embryonic cells as well as highly differentiating cells such as trichomes. A translational fusion with the enhanced yellow fluorescent protein indicates that AtFIP37 is a nuclear protein localized in multiple subnuclear foci that show a speckled distribution pattern. Overexpression of AtFIP37 in transgenic lines induces the formation of large trichome cells with up to six branches. These large trichomes have a DNA content up to 256C, implying that these cells have undergone extra rounds of endoreduplication. Altogether, these data show that AtFIP37 is critical for life in Arabidopsis and implies a role for AtFIP37 in the regulation of the cell cycle as shown for FKBP12 and TOR (target of rapamycin) in mammals.