Transcriptional regulation of the human ADP-ribosylation factor 5 (ARF5) gene

Arf5-mediated regulation of mTORC1 at the plasma membrane

The mechanistic target of rapamycin (mTOR) kinase regulates a major signaling pathway in eukaryotic cells. In addition to regulation of mTORC1 at lysosomes, mTORC1 is also localized at other locations. However, little is known about the recruitment and activation of mTORC1 at nonlysosomal sites. To identify regulators of mTORC1 recruitment to nonlysosomal compartments, novel interacting partners with the mTORC1 subunit, Raptor, were identified using immunoprecipitation and mass spectrometry. We show that one of the interacting partners, Arf5, is a novel regulator of mTORC1 signaling at plasma membrane ruffles. Arf5-GFP localizes with endogenous mTOR at PI3,4P2-enriched membrane ruffles together with the GTPase required for mTORC1 activation, Rheb. Knockdown of Arf5 reduced the recruitment of mTOR to membrane ruffles. The activation of mTORC1 at membrane ruffles was directly demonstrated using a plasma membrane-targeted mTORC1 biosensor, and Arf5 was shown to enhance the phosphorylation of the mTORC1 biosensor substrate. In addition, endogenous Arf5 was shown to be required for rapid activation of mTORC1-mediated S6 phosphorylation following nutrient starvation and refeeding. Our findings reveal a novel Arf5-dependent pathway for recruitment and activation of mTORC1 at plasma membrane ruffles, a process relevant for spatial and temporal regulation of mTORC1 by receptor and nutrient stimuli.

Characterization of the 5'-flanking regions of the sea anemone ADP ribosylation factor 1 and actin genes

The 5'-flanking regions of the sea anemone, Aiptasia pulchella (ap) ARF1 gene showed the absence of a TATA box. The transcriptional start site determined by 5' rapid amplification of cDNA ends (5'RACE) is located 75 base pairs upstream of the translational start site. Transfection experiments in HeLa and COS-7 cells demonstrate that all the elements required to achieve significant basal transcription activity are located between position -208 and -88 relative to the transcriptional start site. There are three consensus initiator (Inr) elements for TATA-less promoter around the transcriptional start site of the apARF1 gene (+29, -158, and -226) that are likely to play roles in the regulation. For the apactin gene, the 5'-flanking region contains a TATA box located 30 base pairs upstream of the transcriptional start site. The transient transfection of apactin/luciferase deletion constructs revealed that the TATA box indeed is necessary for full expression.

Gene expression profiling in polycythaemia vera: overexpression of transcription factor NF-E2

Summary The molecular aetiology of polycythaemia vera (PV) remains unknown and the differential diagnosis between PV and secondary erythrocytosis (SE) can be challenging. Gene expression profiling can identify candidates involved in the pathophysiology of PV and generate a molecular signature to aid in diagnosis. We thus performed cDNA microarray analysis on 40 PV and 12 SE patients. Two independent data sets were obtained: using a two-step training/validation design, a set of 64 genes (class predictors) was determined, which correctly discriminated PV from SE patients. Separately 253 genes were identified to be upregulated and 391 downregulated more than 1.5-fold in PV compared with healthy controls (P < 0.01). Of the genes overexpressed in PV, 27 contained Sp1 sites: we therefore propose that altered activity of Sp1-like transcription factors may contribute to the molecular aetiology of PV. One Sp1 target, the transcription factor NF-E2 [nuclear factor (erythroid-derived 2)], is overexpressed 2- to 40-fold in PV patients. In PV bone marrow, NF-E2 is overexpressed in megakaryocytes, erythroid and granulocytic precursors. It has been shown that overexpression of NF-E2 leads to the development of erythropoietin-independent erythroid colonies and that ectopic NF-E2 expression can reprogram monocytic cells towards erythroid and megakaryocytic differentiation. Transcription factor concentration may thus control lineage commitment. We therefore propose that elevated concentrations of NF-E2 in PV patients lead to an overproduction of erythroid and, in some patients, megakaryocytic cells/platelets. In this model, the level of NF-E2 overexpression determines both the severity of erythrocytosis and the concurrent presence or absence of thrombocytosis.

The role of ADP-ribosylation factor and SAR1 in vesicular trafficking in plants

Ras-like small GTP binding proteins regulate a wide variety of intracellular signalling and vesicular trafficking pathways in eukaryotic cells including plant cells. They share a common structure that operates as a molecular switch by cycling between active GTP-bound and inactive GDP-bound conformational states. The active GTP-bound state is regulated by guanine nucleotide exchange factors (GEF), which promote the exchange of GDP for GTP. The inactive GDP-bound state is promoted by GTPase-activating proteins (GAPs) which accelerate GTP hydrolysis by orders of magnitude. Two types of small GTP-binding proteins, ADP-ribosylation factor (Arf) and secretion-associated and Ras-related (Sar), are major regulators of vesicle biogenesis in intracellular traffic and are founding members of a growing family that also includes Arf-related proteins (Arp) and Arf-like (Arl) proteins. The most widely involved small GTPase in vesicular trafficking is probably Arf1, which not only controls assembly of COPI- and AP1, AP3, and AP4/clathrin-coated vesicles but also recruits other proteins to membranes, including some that may be components of further coats. Recent molecular, structural and biochemical studies have provided a wealth of detail of the interactions between Arf and the proteins that regulate its activity as well as providing clues for the types of effector molecules which are controlled by Arf. Sar1 functions as a molecular switch to control the assembly of protein coats (COPII) that direct vesicle budding from ER. The crystallographic analysis of Sar1 reveals a number of structurally unique features that dictate its function in COPII vesicle formation. In this review, I will summarize the current knowledge of Arf and Sar regulation in vesicular trafficking in mammalian and yeast cells and will highlight recent advances in identifying the elements involved in vesicle formation in plant cells. Additionally, I will briefly discuss the similarities and dissimilarities of vesicle traffic in plant, mammalian and yeast cells.

Sequence, genomic organization, and expression of the human ADP-ribosylation factor 6 (ARF6) gene: a class III ARF

ADP-ribosylation factor 6 (ARF6) is a member of a family of ~20-kDa guanine nucleotide-binding proteins that has been implicated to function in membrane ruffling and cell motility, endocytosis, exocytosis, and membrane recycling. Sequence analysis of the human ARF6 gene indicates it spans 4004 bp, contains a single 98-bp intron within the 5'-untranslated region, and is localized to chromosome 14q21. Similar to the class II ARF transcripts, translation of the ARF6 mRNA initiates in the second exon. Primer extension assays indicate that the major transcription initiation site is located 591 bp 5' to the start of translation, yielding the largest 5'-untranslated region of the known human ARFs. The proximal 5'-flanking region of the human ARF6 gene lacks a TATA box and is highly GC rich. Consistent with this promoter structure, expression analysis of a blot containing 50 human RNAs hybridized with an ARF6-specific oligonucleotide probe revealed that the ARF6 gene is expressed in all tissues; although higher levels of expression were observed in heart, substantia nigra, and kidney. A comparison of the genomic organization of the ARF genes reveals that the ARF6 gene (class III) structure is quite distinct from the class I (ARF1, ARF2, and ARF3) and class II (ARF4 and ARF5) ARF genes.

ZNF143 mediates basal and tissue-specific expression of human transaldolase

Transaldolase regulates redox-dependent apoptosis through controlling NADPH and ribose 5-phosphate production via the pentose phosphate pathway. The minimal promoter sufficient to drive chloramphenicol acetyltransferase reporter gene activity was mapped to nucleotides -49 to -1 relative to the transcription start site of the human transaldolase gene. DNase I footprinting with nuclear extracts of transaldolase-expressing cell lines unveiled protection of nucleotides -29 to -16. Electrophoretic mobility shift assays identified a single dominant DNA-protein complex that was abolished by consensus sequence for transcription factor ZNF143/76 or mutation of the ZNF76/143 motif within the transaldolase promoter. Mutation of an AP-2alpha recognition sequence, partially overlapping the ZNF143 motif, increased TAL-H promoter activity in HeLa cells, without significant impact on HepG2 cells, which do not express AP-2alpha. Cooperativity of ZNF143 with AP-2alpha was supported by supershift analysis of HeLa cells where AP-2 may act as cell type-specific repressor of TAL promoter activity. However, overexpression of full-length ZNF143, ZNF76, or dominant-negative DNA-binding domain of ZNF143 enhanced, maintained, or abolished transaldolase promoter activity, respectively, in HepG2 and HeLa cells, suggesting that ZNF143 initiates transcription from the transaldolase core promoter. ZNF143 overexpression also increased transaldolase enzyme activity. ZNF143 and transaldolase expression correlated in 21 different human tissues and were coordinately upregulated 14- and 34-fold, respectively, in lactating mammary glands compared with nonlactating ones. Chromatin immunoprecipitation studies confirm that ZNF143/73 associates with the transaldolase promoter in vivo. Thus, ZNF143 plays a key role in basal and tissue-specific expression of transaldolase and regulation of the metabolic network controlling cell survival and differentiation.

Preferential expression of ADP-ribosylation factor gene in the chick embryonic gonads

cDNA cloning from chick embryonic gonads subtracted from tissues of the brain, heart, liver, gizzard, mesonephros and skeletal muscle was performed to identify genes with expression unique to embryonic gonads. Several cDNA clones encoding characterized as well as many uncharacterized genes were obtained. ADP-ribosylation factor (ARF) of these identified genes was preferentially expressed in the chick embryonic ovary and testis as revealed by reverse transcription-polymerase chain reaction analysis. Expression of the ARF was evaluated through embryonic development, but no difference in the transcript (relative to glyceraldehyde-3-phosphate dehydrogenase transcript) was observed between the left and right ovaries, and between the ovary and testis. In addition, the ARF transcript was detected in the gonads on embryonic days 5 to 21. These findings indicate that the ARF is constantly, but preferentially expressed in the embryonic gonads during development.

Cloning and characterization of the human ADP-ribosylation factor 4 gene

ADP-ribosylation factor 4 (ARF4) is a member of a family of approximately 20 kDa guanine nucleotide-binding proteins that were initially identified by their ability to stimulate the ADP-ribosyltransferase activity of cholera toxin in vitro. They have recently been shown to play a role in vesicular trafficking and as activators of phospholipase D. The organization of the human ARF4 gene was determined from a genomic clone isolated from an arrayed PAC genomic library. The gene spans approximately 12 kb and contains six exons and five introns. Translation initiates in exon 1 and terminates in exon 6. Nuclease protection experiments indicated that the major transcription initiation site is located 211 bp 5' to the start of translation. In some cell lines derived from human tissues, however, multiple initiation sites were observed. The proximal 5'-flanking region of the human ARF4 gene lacks a TATA box, is highly GC rich, and contains multiple potential Spl-binding sites. An alignment of the exons for the class I ARF genes (ARF1, ARF2, and ARF3) and class II ARF genes (ARF4 and ARF5) reveals that the members of each class share a common gene organization. The structures of the class I and II ARF genes, however, are quite distinct and support the division of the ARFs into these groups based on deduced amino acid sequence, protein size, phylogenetic analysis, and gene structure.