Synthetic genetic array analysis of the PtdIns 4-kinase Pik1p identifies components in a Golgi-specific Ypt31/rab-GTPase signaling pathway

Phosphorylated derivatives of phosphatidylinositol are essential regulators of both endocytic and exocytic trafficking in eukaryotic cells. In Saccharomyces cerevisiae, the phosphatidylinositol 4-kinase, Pik1p generates a distinct pool of PtdIns(4)P that is required for normal Golgi structure and secretory function. Here, we utilize a synthetic genetic array analysis of a conditional pik1 mutant to identify candidate components of the Pik1p/PtdIns(4)P signaling pathway at the Golgi. Our data suggest a mechanistic involvement for Pik1p with a specific subset of Golgi-associated proteins, including the Ypt31p rab-GTPase and the TRAPPII protein complex, to regulate protein trafficking through the secretory pathway. We further demonstrate that TRAPPII specifically functions in a Ypt31p-dependent pathway and identify Gyp2p as the first biologically relevant GTPase activating protein for Ypt31p. We propose that multiple stage-specific signals, which may include Pik1p/PtdIns(4)P, TRAPPII and Gyp2p, impinge upon Ypt31 signaling to regulate Golgi secretory function.     

Precise temporal modulation in the response of the SOS DNA repair network in individual bacteria

The SOS genetic network is responsible for the repair/bypass of DNA damage in bacterial cells. While the initial stages of the response have been well characterized, less is known about the dynamics of the response after induction and its shutoff. To address this, we followed the response of the SOS network in living individual Escherichia coli cells. The promoter activity (PA) of SOS genes was monitored using fluorescent protein-promoter fusions, with high temporal resolution, after ultraviolet irradiation activation. We find a temporal pattern of discrete activity peaks masked in studies of cell populations. The number of peaks increases, while their amplitude reaches saturation, as the damage level is increased. Peak timing is highly precise from cell to cell and is independent of the stage in the cell cycle at the time of damage. Evidence is presented for the involvement of the umuDC operon in maintaining the pattern of PA and its temporal precision, providing further evidence for the role UmuD cleavage plays in effecting a timed pause during the SOS response, as previously proposed. The modulations in PA we observe share many features in common with the oscillatory behavior recently observed in a mammalian DNA damage response. Our results, which reveal a hitherto unknown modulation of the SOS response, underscore the importance of carrying out dynamic measurements at the level of individual living cells in order to unravel how a natural genetic network operates at the systems level.     

The tumor suppressor protein p16(INK4a) and the human papillomavirus oncoprotein-58 E7 are naturally occurring lysine-less proteins that are degraded by the ubiquitin system. Direct evidence for ubiquitination at the N-terminal residue

Conjugation of ubiquitin to an internal lysine is the initial step in the degradation of the majority of the substrates of the ubiquitin system. For several substrates, it has been shown that the first ubiquitin moiety is conjugated to the N-terminal residue. In all these substrates, however, the internal lysines also played a role in modulating their stability. To better understand the physiological significance of this novel mode of modification, it was important to identify proteins in which degradation is completely dependent on N-terminal ubiquitination. Also, although the experimental evidence for N-terminal ubiquitination is rather strong, nevertheless, it has remained indirect. Here we demonstrate that an important group of proteins that are targeted via N-terminal ubiquitination are the naturally occurring lysine-less proteins such as the human papillomavirus (HPV)-58 E7 oncoprotein and the cell cycle inhibitor and tumor suppressor p16(INK4a). For these proteins, the only residue that can be targeted is the N-terminal residue. Interestingly, p16(INK4a) is degraded in a cell density-dependent manner. Importantly, we provide for the first time direct evidence for N-terminal ubiquitination. Analysis of tryptic digest of the ubiquitin conjugate of HPV-58 E7 revealed a fusion peptide that is composed of the C-terminal domain of ubiquitin and the N-terminal domain of E7. With the abundance of native lysine-less proteins, among which are important viral and cell regulators, this novel mode of protein targeting has implications for both physiological and pathophysiological processes.     

Chemoattractant signals and beta 2 integrin occupancy at apical endothelial contacts combine with shear stress signals to promote transendothelial neutrophil migration

Lymphocyte transendothelial migration (TEM) is promoted by fluid shear signals and apical endothelial chemokines. Studying the role of these signals in neutrophil migration across differently activated HUVEC in a flow chamber apparatus, we gained new insights into how neutrophils integrate multiple endothelial signals to promote TEM. Neutrophils crossed highly activated HUVEC in a beta(2) integrin-dependent manner but independently of shear. In contrast, neutrophil migration across resting or moderately activated endothelium with low-level beta(2) integrin ligand activity was dramatically augmented by endothelial-presented chemoattractants, conditional to application of physiological shear stresses and intact beta(2) integrins. Shear stress signals were found to stimulate extensive neutrophil invaginations into the apical endothelial interface both before and during TEM. A subset of invaginating neutrophils completed transcellular diapedesis through individual endothelial cells within <1 min. Our results suggest that low-level occupancy of beta(2) integrins by adherent neutrophils can mediate TEM only if properly coupled to stimulatory shear stress and chemoattractant signals transduced at the apical neutrophil-endothelial interface.     

A chromoplast-specific carotenoid biosynthesis pathway is revealed by cloning of the tomato white-flower locus

Carotenoids and their oxygenated derivatives xanthophylls play essential roles in the pigmentation of flowers and fruits. Wild-type tomato (Solanum lycopersicum) flowers are intensely yellow due to accumulation of the xanthophylls neoxanthin and violaxanthin. To study the regulation of xanthophyll biosynthesis, we analyzed the mutant white-flower (wf). It was found that the recessive wf phenotype is caused by mutations in a flower-specific beta-ring carotene hyroxylase gene (CrtR-b2). Two deletions and one exon-skipping mutation in different CrtR-b2 wf alleles abolish carotenoid biosynthesis in flowers but not leaves, where the homologous CrtR-b1 is constitutively expressed. A second beta-carotene hydroxylase enzyme as well as flower- and fruit-specific geranylgeranyl diphosphate synthase, phytoene synthase, and lycopene beta-cyclase together define a carotenoid biosynthesis pathway active in chromoplasts only, underscoring the crucial role of gene duplication in specialized plant metabolic pathways. We hypothesize that this pathway in tomato was initially selected during evolution to enhance flower coloration and only later recruited to enhance fruit pigmentation. The elimination of beta-carotene hydroxylation in wf petals results in an 80% reduction in total carotenoid concentration, possibly caused by the inability of petals to store high concentrations of carotenoids other than xanthophylls and by degradation of beta-carotene, which accumulates as a result of the wf mutation but is not due to altered expression of genes in the biosynthetic pathway.     

Bacterial programmed cell death and multicellular behavior in bacteria

Traditionally, programmed cell death (PCD) is associated with eukaryotic multicellular organisms. However, recently, PCD systems have also been observed in bacteria. Here we review recent research on two kinds of genetic programs that promote bacterial cell death. The first is mediated by mazEF, a toxin–antitoxin module found in the chromosomes of many kinds of bacteria, and mainly studied in Escherichia coli. The second program is found in Bacillus subtilis, in which the skf and sdp operons mediate the death of a subpopulation of sporulating bacterial cells. We relate these two bacterial PCD systems to the ways in which bacterial populations resemble multicellular organisms.     

The F-BAR domain of SRGP-1 facilitates cell-cell adhesion during C. elegans morphogenesis

Robust cell-cell adhesion is critical for tissue integrity and morphogenesis, yet little is known about the molecular mechanisms controlling cell-cell junction architecture and strength. We discovered that SRGP-1 is a novel component of cell-cell junctions in Caenorhabditis elegans, localizing via its F-BAR (Bin1, Amphiphysin, and RVS167) domain and a flanking 200-amino acid sequence. SRGP-1 activity promotes an increase in membrane dynamics at nascent cell-cell contacts and the rapid formation of new junctions; in addition, srgp-1 loss of function is lethal in embryos with compromised cadherin-catenin complexes. Conversely, excess SRGP-1 activity leads to outward bending and projections of junctions. The C-terminal half of SRGP-1 interacts with the N-terminal F-BAR domain and negatively regulates its activity. Significantly, in vivo structure-function analysis establishes a role for the F-BAR domain in promoting rapid and robust cell adhesion during embryonic closure events, independent of the Rho guanosine triphosphatase-activating protein domain. These studies establish a new role for this conserved protein family in modulating cell-cell adhesion.     

Occupancy of lymphocyte LFA-1 by surface-immobilized ICAM-1 is critical for TCR- but not for chemokine-triggered LFA-1 conversion to an open headpiece high-affinity state

Lymphocyte arrest and spreading on ICAM-1-expressing APCs require activation of lymphocyte LFA-1 by TCR signals, but the conformational switches of this integrin during these critical processes are still elusive. Using Ab probes that distinguish between different LFA-1 conformations, we found that, unlike strong chemokine signals, potent TCR stimuli were insufficient to trigger LFA-1 extension or headpiece opening in primary human lymphocytes. Nevertheless, LFA-1 in these TCR-stimulated T cells became highly adhesive to both anchored and mobile surface-bound ICAM-1, although it failed to bind soluble ICAM-1 with measurable affinity. Rapid rearrangement of LFA-1 by immobilized ICAM-1 switched the integrin to an open headpiece conformation within numerous scattered submicron focal dots that did not readily collapse into a peripheral LFA-1 ring. Headpiece-activated LFA-1 microclusters were enriched with talin but were devoid of TCR and CD45. Notably, LFA-1 activation by TCR signals as well as subsequent T cell spreading on ICAM-1 took place independently of cytosolic Ca(2+). In contrast to LFA-1-activating chemokine signals, TCR activation of LFA-1 readily took place in the absence of external shear forces. LFA-1 activation by TCR signals also did not require internal myosin II forces but depended on intact actin cytoskeleton. Our results suggest that potent TCR signals fail to trigger LFA-1 headpiece activation unless the integrin first gets stabilized by surface-bound ICAM-1 within evenly scattered actin-dependent LFA-1 focal dots, the quantal units of TCR-stimulated T cell arrest and spreading on ICAM-1.     

The DR1 and DR6 First Exons of Human Herpesvirus 6A Are Not Required for Virus Replication in Culture and Are Deleted in Virus Stocks That Replicate Well in T-Cell Lines

Human herpesvirus 6A (HHV-6A) and HHV-6B are lymphotropic viruses which replicate in cultured activated cord blood mononuclear cells (CBMCs) and in T-cell lines. Viral genomes are composed of 143-kb unique (U) sequences flanked by ∼8- to 10-kb left and right direct repeats, DR_L and DR_R. We have recently cloned HHV-6A (U1102) into bacterial artificial chromosome (BAC) vectors, employing DNA replicative intermediates. Surprisingly, HHV-6A BACs and their parental DNAs were found to contain short ∼2.7-kb DRs. To test whether DR shortening occurred during passaging in CBMCs or in the SupT1 T-cell line, we compared packaged DNAs from various passages. Restriction enzymes, PCR, and sequencing analyses have shown the following. (i) Early (1992) viral preparations from CBMCs contained ∼8-kb DRs. (ii) Viruses currently propagated in SupT1 cells contained ∼2.7-kb DRs. (iii) The deletion spans positions 60 to 5545 in DR_L, including genes encoded by DR1 through the first exon of DR6. The pac-2-pac-1 packaging signals, the DR7 open reading frame (ORF), and the DR6 second exon were not deleted. (iv) The DR_R sequence was similarly shortened by 5.4 kb. (v) The DR1 through DR6 first exon sequences were deleted from the entire HHV-6A BACs, revealing that they were not translocated into other genome locations. (vi) When virus initially cultured in CBMCs was passaged in SupT1 cells no DR shortening occurred. (vii) Viral stocks possessing short DRs replicated efficiently, revealing the plasticity of herpesvirus genomes. We conclude that the DR deletion occurred once, producing virus with advantageous growth “conquering” the population. The DR1 gene and the first DR6 exon are not required for propagation in culture.Human herpesvirus 6 (HHV-6) is a member of the Betaherpesvirus subfamily, as recently reviewed (46). The virus can enter hematopoietic cells, including T cells, B cells, natural killer (NK) cells, monocytes, and dendritic cells (DCs), as well as nonhematopoietic cells, as reviewed in references 8, 17, and 46. In culture, the virus replicates in activated peripheral blood lymphocytes (PBLs), cord blood mononuclear cells (CBMCs), and in T-cell lines (1, 17, 46). HHV-6 isolates fall into two distinct classes designated as HHV-6A and HHV-6B variants. The two variants can be distinguished by their restriction enzyme patterns, antigenicity, DNA sequences, and disease association (1, 36, 46). HHV-6B is the causative agent of roseola infantum, a prevalent children''s disease characterized by high fever and skin rash (47). In rare cases, the virus exhibits neurotropism and has been found in children experiencing convulsions up to lethal encephalitis (1, 21, 46, 48).HHV-6B reactivation from latency was found to occur in patients receiving immunosuppressive treatment in bone marrow and other transplantations. This was associated with febrile illness, delayed transplant engraftment, and neurological involvement, up to lethal encephalitis (5, 13, 34, 46). HHV-6A has thus far no clear disease association, although several studies have suggested central nervous system (CNS) tropism, including aggravation of symptoms in patients with multiple sclerosis (MS) (6, 14, 33, 41).HHV-6A and HHV-6B share general genomic architecture. The unit-length DNA molecules are approximately 160 kb, composed of a 143-kb unique (U) segment flanked by left and right direct repeats (DR_L and DR_R, respectively) (19, 24, 27, 46). The DRs are of sizes 8 to 10 kb in different viral isolates (2, 19, 24, 46). In both the HHV-6A and HHV-6B genomes, the herpesvirus conserved cleavage/packaging signals pac-1 and pac-2 (9, 15, 17) are located at the left and the right termini of the DRs (17, 19, 46). The PubMed sequence for the U1102 strain (accession no. {"type":"entrez-nucleotide","attrs":{"text":"NC_001664","term_id":"1344462938","term_text":"NC_001664"}}NC_001664) starts with the pac-1 signal at positions 1 to 56, followed by multiple copies of perfect and imperfect telomere-like sequences, up to position 418. It was suggested that the telomeric repeats may have originated from host cell chromosomal telomeres (43). Additionally, the DR encodes several open reading frames (ORFs), four of which are dealt with in our paper: (i) the spliced DR1 at positions 501 to 759 and 843 to 2653; (ii) DR5 at positions 3738 to 4164; (iii) the spliced DR6 at positions 4725 to 5028 and 5837 to 6720; and (iv) an ORF of DR7, at positions 5629 to 6720, partially overlapping the DR6 gene (20). Hollsberg and coworkers (37) have recently found that the homologous gene in HHV-6B encodes a nuclear protein that forms a complex with viral DNA processivity factor p41. Gompels and coworkers have also shown that DR1 and DR6 are partly homologous to the human cytomegalovirus (HCMV) US22 gene family. Both have a CXC motif: DR1 with homology to the HCMV US26 gene and DR6 with homology to the HCMV US22 gene (20). The map continues with reiterated perfect hexanucleotide telomeric sequences (GGGTAA)_n at positions 7655 to 8008 (19, 43). The number of telomeric repeats was found to vary in different viral strains (2, 43). The DR terminates with the pac-2 signal.We have recently cloned the intact HHV-6A genome into bacterial artificial chromosomes (BACs), by direct cloning of unit-length DNA produced from circular or head-to-tail replication intermediates into modified BAC vectors containing the green fluorescent protein (GFP) marker and ampicillin-puromycin (Amp-Puro) selection cassette (3). Surprisingly, the HHV-6A BAC clones as well as the parental HHV-6A (U1102) propagated in our laboratory in SupT1 cells were found to contain DRs of ∼2.7 kb instead of the expected ∼8- to 10-kb DRs, as in the early publications (19, 24, 27, 46) and in the PubMed sequence. This has raised the following questions. When did the deleted DRs arise? What was the detailed structure of deleted DRs?HHV-6 was discovered by Gallo and colleagues in 1986 (35), and viral isolates were obtained in multiple laboratories from AIDS patients, patients with lymphoproliferative disorders, and patients with roseola infantum (12, 26, 42, 45, 47). The isolates were propagated initially in activated PBLs and CBMCs and then in continuous T-cell lines, including HSB-2, J-JHAN, SupT1, Molt-3, and MT-4 (11, 45). The U1102 strain isolated by Downing and colleagues (12) was contributed to our laboratory by Robert Honess and was propagated first in activated PBLs and CBMCs (11, 18, 36, 45) and then in J-JHAN and SupT1 T cells (4, 30). To answer the question with regard to the origin of the short DRs and their structure, we have compared earlier viral HHV-6A passages with the currently propagated virus and the HHV-6A BAC clones. We describe here the detailed structure of the DR_L and DR_R of the “new” virus, containing the short ∼2.7-kb DR. We show that the deletion contained the left multiple repeats of telomere-like sequences and the ORFs from DR1 up to the DR6 first exon. Review of viral passaging since 1992 indicated that the deletion occurred spontaneously. The deleted viruses were stably and efficiently propagated in SupT1 T cells, indicating that the DR1 and DR6 first exons are not essential for virus in vitro replication.