Fog-1, a Regulatory Gene Required for Specification of Spermatogenesis in the Germ Line of Caenorhabditis Elegans

In wild-type Caenorhabditis elegans, the XO male germ line makes only sperm and the XX hermaphrodite germ line makes sperm and then oocytes. In contrast, the germ line of either a male or a hermaphrodite carrying a mutation of the fog-1 (feminization of the germ line) locus is sexually transformed: cells that would normally make sperm differentiate as oocytes. However, the somatic tissues of fog-1 mutants remain unaffected. All fog-1 alleles identified confer the same phenotype. The fog-1 mutations appear to reduce fog-1 function, indicating that the wild-type fog-1 product is required for specification of a germ cell as a spermatocyte. Two lines of evidence indicate that a germ cell is determined for sex at about the same time that it enters meiosis. These include the fog-1 temperature sensitive period, which coincides in each sex with first entry into meiosis, and the phenotype of a fog-1; glp-1 double mutant. Experiments with double mutants show that fog-1 is epistatic to mutations in all other sex-determining genes tested. These results lead to the conclusion that fog-1 acts at the same level as the fem genes at the end of the sex determination pathway to specify germ cells as sperm.     

Coordination of the Vernalization Response through a VIN3 and FLC Gene Family Regulatory Network in Arabidopsis

Vernalization is an environmentally induced epigenetic switch in which winter cold triggers epigenetic silencing of floral repressors and thus provides competence to flower in spring. Vernalization triggers the recruitment of chromatin-modifying complexes to a clade of flowering repressors that are epigenetically silenced via chromatin modifications. In Arabidopsis thaliana, VERNALIZATION INSENSITIVE3 (VIN3) and its related plant homeodomain finger proteins act together with Polycomb Repressive Complex 2 to increase repressive histone marks at floral repressor loci, including FLOWERING LOCUS C (FLC) and its related genes, by vernalization. Here, we show that VIN3 family of proteins nonredundantly functions to repress different subsets of the FLC gene family during the course of vernalization. Each VIN3 family protein binds to modified histone peptides in vitro and directly associates with specific sets of FLC gene family chromatins in vivo to mediate epigenetic silencing. In addition, members of the FLC gene family are also differentially regulated during the course of vernalization to mediate proper vernalization response. Our results show that these two gene families cooperated during the course of evolution to ensure proper vernalization response through epigenetic changes.     

Characterization of Xylan Utilization and Discovery of a New Endoxylanase in Thermoanaerobacterium saccharolyticum through Targeted Gene Deletions

The economical production of fuels and commodity chemicals from lignocellulose requires the utilization of both the cellulose and hemicellulose fractions. Xylanase enzymes allow greater utilization of hemicellulose while also increasing cellulose hydrolysis. Recent metabolic engineering efforts have resulted in a strain of Thermoanaerobacterium saccharolyticum that can convert C₅ and C₆ sugars, as well as insoluble xylan, into ethanol at high yield. To better understand the process of xylan solubilization in this organism, a series of targeted deletions were constructed in the homoethanologenic T. saccharolyticum strain M0355 to characterize xylan hydrolysis and xylose utilization in this organism. While the deletion of β-xylosidase xylD slowed the growth of T. saccharolyticum on birchwood xylan and led to an accumulation of short-chain xylo-oligomers, no other single deletion, including the deletion of the previously characterized endoxylanase XynA, had a phenotype distinct from that of the wild type. This result indicates a multiplicity of xylanase enzymes which facilitate xylan degradation in T. saccharolyticum. Growth on xylan was prevented only when a previously uncharacterized endoxylanase encoded by xynC was also deleted in conjunction with xynA. Sequence analysis of xynC indicates that this enzyme, a low-molecular-weight endoxylanase with homology to glycoside hydrolase family 11 enzymes, is secreted yet untethered to the cell wall. Together, these observations expand our understanding of the enzymatic basis of xylan hydrolysis by T. saccharolyticum.     

Regulation of per and cry Genes Reveals a Central Role for the D-Box Enhancer in Light-Dependent Gene Expression

Light serves as a key environmental signal for synchronizing the circadian clock with the day night cycle. The zebrafish represents an attractive model for exploring how light influences the vertebrate clock mechanism. Direct illumination of most fish tissues and cell lines induces expression of a broad range of genes including DNA repair, stress response and key clock genes. We have previously identified D- and E-box elements within the promoter of the zebrafish per2 gene that together direct light-induced gene expression. However, is the combined regulation by E- and D-boxes a general feature for all light-induced gene expression? We have tackled this question by examining the regulation of additional light-inducible genes. Our results demonstrate that with the exception of per2, all other genes tested are not induced by light upon blocking of de novo protein synthesis. We reveal that a single D-box serves as the principal light responsive element within the cry1a promoter. Furthermore, upon inhibition of protein synthesis D-box mediated gene expression is abolished while the E-box confers light driven activation as observed in the per2 gene. Given the existence of different photoreceptors in fish cells, our results implicate the D-box enhancer as a general convergence point for light driven signaling.     

The Promoter of the Immunoglobulin J Chain Gene Receives Its Authentic Enhancer Activity through the Abutting MEF2 and PU.1 Sites in a DNA-Looping Interaction

Immunoglobulin J chain (IgJ) promoter had previously been dissected in the context of a heterologous enhancer and/or promoter because its strength was weak and its authentic enhancer was not available at that time. Thus, it has been questioned whether the previous dissection of the IgJ promoter might also be relevant in the context of its authentic enhancer. Now that the authentic IgJ enhancer has been identified, redelineation of the IgJ promoter could be performed in the context of this authentic enhancer. In this redelineation, the previously identified MEF2 and PU.1 sites were shown to be critical for communicating with its authentic enhancer and thereby for receiving enhancer activity. In accordance with this finding, a DNA-looping interaction between the IgJ promoter and its enhancer was demonstrated using chromosome conformation capture assays not only in IgJ-expressing S194 plasma cells but also during interleukin-2-induced BCL1 B-cell terminal differentiation. Furthermore, MEF2 was shown to be reciprocally coimmunoprecipitated with E47, which had been identified to bind to the IgJ enhancer, suggesting that the DNA-looping interaction between the IgJ promoter and its enhancer might be mediated by these proteins. However, the previously identified USF and BSAP sites were shown to be not important for IgJ promoter activity in the context of its authentic enhancer. These findings were further supported by in vivo footprinting and/or chromatin immunoprecipitation assays, which showed the binding of MEF2 and PU.1—but not the binding of USF and BSAP—to the IgJ promoter.     

Requirements for Hedgehog, a Segmental Polarity Gene, in Patterning Larval and Adult Cuticle of Drosophila

Mutations of the hedgehod gene are generally embryonic lethal, resulting in a lawn of denticles on the ventral surface. In strong alleles, no segmentation is obvious and the anteroposterior polarity of ventral denticles is lost. Temperature shift analysis of a temperature-sensitive allele indicates an embryonic activity period for hedgehod between 2.5 and 6 hr of embryonic development (at 25 degrees) and a larval/pupal period from 4 to 7 days of development (at 25 degrees). Mosaic analysis of hedgehod mutations in the adult cuticle indicates a series of defined defects associated with the failure of appropriate hedgehod expression. In particular, defects in the distal portions of the legs and antenna occur in association with homozygous hedgehog clones in the posterior compartment of those structures. Because the defects are associated with homozygous clones, but are not co-extensive, a type of "domineering" nonautonomy is proposed for the activity of the hedgehog gene.     

Stand Still, a Drosophila Gene Involved in the Female Germline for Proper Survival, Sex Determination and Differentiation

We identified a new gene, stand still (stil), required in the female germline for proper survival, sex determination and differentiation. Three strong loss-of-function alleles were isolated. The strongest phenotype exhibited by ovaries dissected from adult females is the complete absence of germ cells. In other ovaries, the few surviving germ cells frequently show a morphology typical of primary spermatocytes. still is not required either for fly viability or for male germline development. The gene was cloned and found to encode a novel protein. still is strongly expressed in the female germ cells. Using P[stil(+)] transgenes, we show that stil and a closely localized gene are involved in the modification of the ovarian phenotypes of the dominant alleles of ovo caused by heterozygosity of region 49 A-D. The similarity of the mutant phenotypes of stil to that of otu and ovo suggests that the three genes function in a common or in parallel pathways necessary in the female germline for its survival, sex determination and differentiation.     

A Genetic Analysis of Pannier, a Gene Necessary for Viability of Dorsal Tissues and Bristle Positioning in Drosophila

A genetic and phenotypic analysis of the gene pannier is described. Animals mutant for strong alleles die as embryos in which the cells of the amnioserosa are prematurely lost. This leads to a dorsal cuticular hole. The dorsal-most cells of the imagos are also affected: viable mutants exhibit a cleft along the dorsal midline. pannier mRNA accumulates specifically in the dorsal-most regions of the embryo and the imaginal discs. Viable mutants and mutant combinations also affect the thoracic and head bristle patterns in a complex fashion. Only those bristles within the area of expression of pannier are affected. A large number of alleles have been studied and reveal that pannier may have opposing effects on the expression of achaete and scute leading to a loss or a gain of bristles.     

kakapo, a Gene Required for Adhesion Between and Within Cell Layers in Drosophila, Encodes a Large Cytoskeletal Linker Protein Related to Plectin and Dystrophin

Mutations in kakapo were recovered in genetic screens designed to isolate genes required for integrin-mediated adhesion in Drosophila. We cloned the gene and found that it encodes a large protein (>5,000 amino acids) that is highly similar to plectin and BPAG1 over the first 1,000–amino acid region, and contains within this region an α-actinin type actin-binding domain. A central region containing dystrophin-like repeats is followed by a carboxy domain that is distinct from plectin and dystrophin, having neither the intermediate filament-binding domain of plectin nor the dystroglycan/syntrophin-binding domain of dystrophin. Instead, Kakapo has a carboxy terminus similar to the growth arrest–specific protein Gas2. Kakapo is strongly expressed late during embryogenesis at the most prominent site of position-specific integrin adhesion, the muscle attachment sites. It is concentrated at apical and basal surfaces of epidermal muscle attachment cells, at the termini of the prominent microtubule bundles, and is required in these cells for strong attachment to muscles. Kakapo is also expressed more widely at a lower level where it is essential for epidermal cell layer stability. These results suggest that the Kakapo protein forms essential links among integrins, actin, and microtubules.     

Genetic Characterization of Small Ovaries, a Gene Required in the Soma for the Development of the Drosophila Ovary and the Female Germline

The small ovary gene (sov) is required for the development of the Drosophila ovary. Six EMS-induced recessive alleles have been identified. Hypomorphic alleles are female sterile and have no effect on male fertility, whereas more severe mutations result in lethality. The female-sterile alleles produce a range of mutant phenotypes that affect the differentiation of both somatic and germline tissues. These mutations generally produce small ovaries that contain few egg cysts and disorganized ovarioles, and in the most extreme case no ovarian tissue is present. The mutant egg cysts that develop have aberrant morphology, including abnormal numbers of nurse cells and patches of necrotic cells. We demonstrate that sov gene expression is not required in the germline for the development of functional egg cysts. This indicates that the sov function is somatic dependent. We present evidence using loss-of-function and constitutive forms of the somatic sex regulatory genes that sov activity is essential for the development of the somatic ovary regardless of the chromosomal sex of the fly. In addition, the genetic mapping of the sov locus is presented, including the characterization of two lethal sov alleles and complementation mapping with existing rearrangements.     

Binding Pockets and Pathways for Dioxygen through the KijD3 N‐Oxygenase in Complex with Flavin Mononucleotide Cofactor and a 3‐Aminoglucose Substrate: Predictions from Molecular Dynamics Simulations

In this work, two protein systems, Kij3D? FMN? AKM? O₂ and Kij3D? FMN? O₂, made of KijD3 N‐oxygenase, flavin mononucleotide (FMN) cofactor, dTDP‐3‐amino‐2,3,6‐trideoxy‐4‐keto‐3‐methyl‐D ‐glucose (AKM) substrate, and dioxygen (O₂), have been assembled by adding a molecule of O₂, and removing (or not) AKM, to crystal data for the Kij3D? FMN? AKM complex. Egress of AKM and O₂ from these systems was then investigated by applying a tiny external random force, in turn, to their center of mass in the course of molecular dynamics in explicit H₂O. It turned out that the wide AKM channel, even when emptied, does not constitute the main route for O₂ egress. Other routes appear to be also viable, while various binding pockets (BPs) outside the active center are prone to trap O₂. By reversing the reasoning, these can also be considered as routes for uptake of O₂ by the protein, before or after AKM uptake, while BPs may serve as reservoirs of O₂. This shows that the small molecule O₂ is capable of permeating the protein by exploiting all nearby interstices that are created on thermal fluctuations of the protein, rather than having necessarily to look for farther, permanent channels.