Roles of hesC and gcm in echinoid larval mesenchyme cell development

To understand the roles of hesC and gcm during larval mesenchyme specification and differentiation in echinoids, we performed perturbation experiments for these genes in two distantly related euechinoids, Hemicentrotus pulcherrimus and Scaphechinus mirabilis. The number of larval mesenchyme cells increased when the translation of hesC was inhibited, thereby suggesting that hesC has a general role in larval mesenchyme development. We confirmed previous results by demonstrating that gcm is involved in pigment cell differentiation. Simultaneous inhibition of the translation of hesC and gcm induced a significant increase in the number of skeletogenic cells, which suggests that gcm functions in skeletogenic fate repression. Based on these observations, we suggest that: (i) hesC participates in some general aspects of mesenchymal cell development; and (ii) gcm is involved in the mechanism responsible for the binary specification of skeletogenic and pigment cell fates.     

Precise cis-regulatory control of spatial and temporal expression of the alx-1 gene in the skeletogenic lineage of s. purpuratus

Deployment of the gene-regulatory network (GRN) responsible for skeletogenesis in the embryo of the sea urchin Strongylocentrotus purpuratus is restricted to the large micromere lineage by a double negative regulatory gate. The gate consists of a GRN subcircuit composed of the pmar1 and hesC genes, which encode repressors and are wired in tandem, plus a set of target regulatory genes under hesC control. The skeletogenic cell state is specified initially by micromere-specific expression of these regulatory genes, viz. alx1, ets1, tbrain and tel, plus the gene encoding the Notch ligand Delta. Here we use a recently developed high throughput methodology for experimental cis-regulatory analysis to elucidate the genomic regulatory system controlling alx1 expression in time and embryonic space. The results entirely confirm the double negative gate control system at the cis-regulatory level, including definition of the functional HesC target sites, and add the crucial new information that the drivers of alx1 expression are initially Ets1, and then Alx1 itself plus Ets1. Cis-regulatory analysis demonstrates that these inputs quantitatively account for the magnitude of alx1 expression. Furthermore, the Alx1 gene product not only performs an auto-regulatory role, promoting a fast rise in alx1 expression, but also, when at high levels, it behaves as an auto-repressor. A synthetic experiment indicates that this behavior is probably due to dimerization. In summary, the results we report provide the sequence level basis for control of alx1 spatial expression by the double negative gate GRN architecture, and explain the rising, then falling temporal expression profile of the alx1 gene in terms of its auto-regulatory genetic wiring.     

A novel role of BELL1-like homeobox genes, PENNYWISE and POUND-FOOLISH, in floral patterning

Flowers are determinate shoots comprised of perianth and reproductive organs displayed in a whorled phyllotactic pattern. Floral organ identity genes display region-specific expression patterns in the developing flower. In Arabidopsis, floral organ identity genes are activated by LEAFY (LFY), which functions with region-specific co-regulators, UNUSUAL FLORAL ORGANS (UFO) and WUSCHEL (WUS), to up-regulate homeotic genes in specific whorls of the flower. PENNYWISE (PNY) and POUND-FOOLISH (PNF) are redundant functioning BELL1-like homeodomain proteins that are expressed in shoot and floral meristems. During flower development, PNY functions with a co-repressor complex to down-regulate the homeotic gene, AGAMOUS (AG), in the outer whorls of the flower. However, the function of PNY as well as PNF in regulating floral organ identity in the central whorls of the flower is not known. In this report, we show that combining mutations in PNY and PNF enhance the floral patterning phenotypes of weak and strong alleles of lfy, indicating that these BELL1-like homeodomain proteins play a role in the specification of petals, stamens and carpels during flower development. Expression studies show that PNY and PNF positively regulate the homeotic genes, APETALA3 and AG, in the inner whorls of the flower. Moreover, PNY and PNF function in parallel with LFY, UFO and WUS to regulate homeotic gene expression. Since PNY and PNF interact with the KNOTTED1-like homeodomain proteins, SHOOTMERISTEMLESS (STM) and KNOTTED-LIKE from ARABIDOPSIS THALIANA2 (KNAT2) that regulate floral development, we propose that PNY/PNF-STM and PNY/PNF-KNAT2 complexes function in the inner whorls to regulate flower patterning events.     

The Egg apparatus 1 gene from maize is a member of a large gene family found in both monocots and dicots

The maize ZmEA1 protein was recently postulated to be involved in short-range pollen tube guidance from the embryo sac. To date, EA1-like sequences had only been identified in monocot species. Using a more conserved C-terminal motif found in the monocot species, numerous ZmEA1-like sequences were retrieved in EST databases from dicot species, as well as from unannotated genomic sequences of Arabidopsis thaliana. RT-PCR analyses were produced for these unannotated genes and showed that these were indeed expressed genes. Further structural and phylogenetic analyses revealed that all members of the EA1-like (EAL) gene family shared a conserved 27–29 amino acid motif, termed the EA box near the C-terminal end, and appear to be secretory proteins. Therefore, the EA box proteins defines a new class of small secretory proteins, some of which being possibly involved in pollen tube guidance. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Expansion and diversification of the signaling capabilities of the CD2/SLAM family in <Emphasis Type="Italic">Xenopodinae</Emphasis> amphibians

We studied the evolution of the CD2 family in tetrapods by extracting and analyzing CD2-like genes from the genome of the amphibian species Silurana (Xenopus) tropicalis. An exhaustive analysis of the genomic and cDNA databases resulted in the identification of at least 70 CD2-like genes. The predicted receptors mostly maintain the typical VC2 ectodomains, but are highly diverse in their C-termini, which suggests a broad range of signaling capacities. Apart from the presumed monomeric receptors with ITSM and/or ITIM motifs, the Silurana family includes secreted proteins. Furthermore, a fraction of the receptors contain a conserved TM subtype with the NxxR motif that is known to promote an association with the FcRγ subunit and that was previously found in the members of the FcR- and KIR-related receptors. The expression analysis of a sample of the genes showed broad tissue distribution and gene-specific expression patterns. Phylogenetic analysis predicted that the CD58, CD150/SLAM, and SLAMF8 genes were maintained as single-copy genes in both mammals and amphibians, while others expanded/contracted in a lineage-specific manner.     

Characterization and expression analysis of TERMINAL FLOWER1 homologs from cultivated alloteraploid cotton (Gossypium hirsutum) and its diploid progenitors

The seasonal cycle and persistence of a plant is governed by a combination of the determinate or indeterminate status of shoot and root apical meristems. A perennial plant is one in which the apical meristem of at least one of its shoot axes remains indeterminate beyond the first growth season.TERMINAL FLOWER1 (TFL1) genes play important roles in regulating flowering time, the fate of inflorescence meristem and perenniality. To investigate the role of TFL1-like genes in the determination of the apical meristems in an industrially important crop cultivated for its fibers, we isolated and characterized two TFL1 homologs (TFL1a and TFL1b) from tetraploid cultivated cotton (Gossypium hirsutum) and its diploid progenitors (Gossypium arboreum and Gossypium raimondii). All isolated genes maintain the same exon–intron organization. Their phylogenetic analysis at the amino acid level confirmed that the isolated sequences are TFL1-like genes and collocate in the TFL1 clade of the PEBP protein family. Expression analysis revealed that the genes TFL1a and TFL1b have slightly different expression patterns, suggesting different functional roles in the determination of the meristems. Additionally, promoter analysis by computational methods revealed the presence of common binding motifs in TFL1-like promoters. These are the first reported TFL1-like genes isolated from cotton, the most important crop for the textile industry.     

Highly Conserved UFD1 Proteins Among Eukaryotes Exhibit Considerable C-Terminus Diversity in Different Taxa

The UFD1 protein is an important ubiquitin recognition component in the ubiquitin-mediated degradation pathway. To investigate the conservation of UFD1 genes among eukaryotes and their differentiation, two UFD1 paralogs from wheat were identified and mapped to homoeologous chromosome groups 6 and 2, respectively. TaUFD1a-6B and TaUFD1b-2D were cloned, and both genes consist of eight introns and of the same intron phases. These genes were compared with those in Arabidopsis, rice, polar, yeast, and mammals for their sequence, chromosome organization, and primary protein structure. The sequence structure, especially those corresponding to the fourth, fifth, and sixth exons of UFD1 genes, is highly conserved across these taxa. However, unlike yeast and mammals having a single UFD1 gene, higher angiosperm species have two ancient UFD1 paralogs. Besides the evolutionarily conserved ubiquitin-binding domain at the N-terminus, plant UFD1 proteins have three conserved C-terminal motifs. Motif I, near the UFD1 domain, displays a high level of similarity to the mammalian p97-binding site, and motif III is likely responsible for endoplasmic reticulum membrane retention. TaUFD1a-6B and TaUFD1b-2D are ubiquitously expressed in different plant tissues. A green fluorescent protein-transient expression assay in epidermal cells of onion demonstrated that TaUFD1 proteins primarily accumulate in the nucleus.     

Domain exchanges between KNAT3 and KNAT1 suggest specificity of the kn1-like homeodomains requires sequences outside of the third helix and N-terminal arm of the homeodomain

Domain exchange constructs that traded regions surrounding the homeodomain were constructed for two kn1 -like genes, KNAT1 and KNAT3, and introduced into Arabidopsis thaliana under the control of the 35S CaMV promoter. The kn1-like homeodomain proteins all have the homeodomain located near the C-terminus of the protein, and also share a second conserved domain (the ELK domain) immediately N-terminal to the homeodomain. Progeny were scored for the appearance of the KNAT1 overexpression phenotype. A construct containing the KNAT3 N-terminus and the KNAT1 ELK- and homeodomain resulted in a KNAT1 overexpression phenotype, indicating that specificity mainly resides within the ELK- and homeodomain region. Further exchanges demonstrated that specificity probably does not arise from a single region within the ELK and/or homeodomain but rather requires sequences both N-terminal and C-terminal to residue 23 of the homeodomain. Further, in contrast to some animal homeodomains, KNAT1 does not utilize the residues of the N-terminal arm of the homeodomain for specificity.     

Purification,crystallization, and preliminary X-ray diffraction analysis of even-skipped homeodomain complexed to DNA

Embryonic development in metazoa, to a significant extent, is directed by genes which contain a conserved sequence motif named the homeobox. This sequence encodes a polypeptide called the homeodomain which has sequence specific DNA-binding activity. We report the purification, crystallization, and preliminary diffraction analysis of the Drosophila Even-skipped homeodomain (Eve HD) bound to two different oligonucleotides. Crystals of Eve HD complexed with an AT-rich sequence belong to space group P2₁, a = 34.06, b = 61.61, c = 39.99 Å, b=90.0°. These crystals diffract to at least 2.0 Å and both native and derivative data sets have been collected. Crystals of Eve HD complexed with a GC-rich sequence belong to space group P6₃, a = b = 124.52, c = 66.78 Å and diffract to 3.5 Å resolution. A native data set has been collected. © 1995 Wiley-Liss, Inc.     

Immunoglobulin D (IgD) of Atlantic cod has a unique structure

 A new immunoglobulin heavy-chain gene with some homology to mammalian IgD was recently cloned from the channel catfish and Atlantic salmon, two species of teleost fish. We have cloned and sequenced a new H-chain gene from Atlantic cod (Gadus morhua L.) which has clear similarities to these genes, but which also differs in several ways. The similarities of catfish, salmon, and cod delta to the mammalian delta genes are sequence homology, location immediately downstream of IgM (mu), and expression by alternative splicing rather than class switching. A unique feature of catfish, salmon, and cod delta is the chimeric nature of the gene product, as the μ1 exon is spliced to the δ1 exon. Several unique features of cod IgD were found: (1) a deletion of the δ3, δ4, δ5, and δ6 domains described in catfish and salmon IgD, (2) a tandem duplication of a part of the delta locus including the δ1 and δ2 domains, (3) the presence of a truncated δ7 domain downstream of the δTM exons, and (4) the separation of the duplicated domains by a short exon (δy) which has homology to a conserved part of the transmembrane exon 1 (TM1) of some H-chain isotypes. This unique organization of the delta locus of cod probably developed after the evolutionary split from the catfish and salmon branches. Received: 18 August 1999 / Revised: 28 December 1999