T47D breast cancer cell growth is inhibited by expression of VACM-1, a cul-5 gene

Vasopressin-activated calcium-mobilizing (VACM-1), a cul-5 gene, is localized on chromosome 11q22-23 close to the gene for Ataxia Telangiectasia in a region associated with a loss of heterozygosity in breast cancer tumor samples. To examine the biological role of VACM-1, we studied the effect of VACM-1 expression on cellular growth and gene expression in T47D breast cancer cells. Immunocytochemistry studies demonstrated that VACM-1 was expressed in 0.6-6% of the T47D cells and localized to the nucleus of mitotic cells. Overexpressing VACM-1 significantly attenuated cellular proliferation and MAPK phosphorylation when compared to the control cells. In addition, VACM-1 decreased egr-1 and increased Fas-L mRNA levels. Further, egr-1 protein levels were significantly lower in the nuclear fraction from VACM-1 transfected cells when compared to controls. These data indicate that VACM-1 is involved in the regulation of cellular growth.     

Long-term effects of sterol depletion in C. elegans: sterol content of synchronized wild-type and mutant populations

Three major long-term effects of sterol deprivation in Caenorhabditis elegans are described. 1) The life expectancy of sterol-deprived wild-type animals is decreased by more than 40%. Similar decreases are found in animals carrying mutations in the daf-9, daf-12, daf-16, and clk-1 genes, suggesting that previously described aging pathways involving these genes are not involved in the life-extending effects of sterols. 2) There is a premature loss of motility, measured by response to mild touch. 3) There is a rapid postreproductive onset of sarcopenia (muscle wasting) as measured by total body fluorescence in a myo3::GFP-expressing strain. We also report that five sterols (the desmethylsterols cholesterol, 7-dehydrocholesterol, and lathosterol and the 4alpha-methyl sterols lophenol and 4alpha-methyl-cholesta-Delta8(14)-en-3beta-ol) are found in significant amounts at all stages of development and aging in cholesterol-fed animals. Supplying any one of these as the sole sterol confers similar protection from the long-term effects of sterol deprivation. These findings suggest that sterols are required continuously throughout the animal's life.     

Neutrophil transendothelial migration in vitro to Streptococcus pneumoniae is pneumolysin dependent

The recruitment of polymorphonuclear leukocytes (PMN) from the vascular space to the alveolar air space is an early event in host defense against pneumococcal pneumonia. Pneumolysin is a virulence factor for Streptococcus pneumoniae, but a specific role for pneumolysin in neutrophil-endothelial cell interactions has not been investigated. Using a Transwell system, we studied in vitro migration of PMNs across a monolayer of human pulmonary microvascular endothelial cells in response to wild-type S. pneumoniae (D39) and a pneumolysin-deficient mutant (plnA(-)) incubated on the abluminal surface of the monolayer. S. pneumoniae induction of PMN migration was dose dependent and elicited by > or =10(5) D39. Mutants lacking pneumolysin had dramatically reduced potency for eliciting PMN migration compared with the parent strain (5 x 10(6) plnA(-) elicits 18.6% PMN migration vs. 55.5% for 5 x 10(6) D39). The disparity between D39 and plnA(-) persisted in ethanol-fixed bacteria, consistent with the properties of pneumolysin. Neither conditioned medium from D39 nor purified pneumolysin elicited PMN migration to the same extent as the intact D39, suggesting that the role of pneumolysin in eliciting PMN migration requires a more complex interaction between the organism, the endothelium, and the PMN. Both D39 and plnA(-) adhered to, and translocated across, the endothelium in the abluminal to luminal direction and elicited similar levels of IL-8 production. Neither strain elicited upregulation of the endothelial adhesion molecules ICAM-1, VCAM-1, or E-selectin, and they did not cause translocation of NF-kappaB to the nucleus. These findings demonstrate a novel role for pneumolysin in pneumococcus-induced PMN recruitment across the pulmonary endothelium.     

Systemic lupus erythematosus

Imerslund-Gräsbeck syndrome (IGS) or selective vitamin B₁₂ (cobalamin) malabsorption with proteinuria is a rare autosomal recessive disorder characterized by vitamin B₁₂ deficiency commonly resulting in megaloblastic anemia, which is responsive to parenteral vitamin B₁₂ therapy and appears in childhood. Other manifestations include failure to thrive and grow, infections and neurological damage. Mild proteinuria (with no signs of kidney disease) is present in about half of the patients. Anatomical anomalies in the urinary tract were observed in some Norwegian patients. Vitamin B₁₂ absorption tests show low absorption, not corrected by administration of intrinsic factor. The symptoms appear from 4 months (not immediately after birth as in transcobalamin deficiency) up to several years after birth. The syndrome was first described in Finland and Norway where the prevalence is about 1:200,000. The cause is a defect in the receptor of the vitamin B₁₂-intrinsic factor complex of the ileal enterocyte. In most cases, the molecular basis of the selective malabsorption and proteinuria involves a mutation in one of two genes, cubilin (CUBN) on chromosome 10 or amnionless (AMN) on chromosome 14. Both proteins are components of the intestinal receptor for the vitamin B₁₂-intrinsic factor complex and the receptor mediating the tubular reabsorption of protein from the primary urine. Management includes life-long vitamin B₁₂ injections, and with this regimen, the patients stay healthy for decades. However, the proteinuria persists. In diagnosing this disease, it is important to be aware that cobalamin deficiency affects enterocyte function; therefore, all tests suggesting general and cobalamin malabsorption should be repeated after abolishment of the deficiency.     

Secreted proteome profiling in human RPE cell cultures derived from donors with age related macular degeneration and age matched healthy donors

Age-related macular degeneration (AMD) is characterized by progressive loss of central vision, which is attributed to abnormal accumulation of macular deposits called "drusen" at the interface between the basal surface of the retinal pigment epithelium (RPE) and Bruch's membrane. In the most severe cases, drusen deposits are accompanied by the growth of new blood vessels that breach the RPE layer and invade photoreceptors. In this study, we hypothesized that RPE secreted proteins are responsible for drusen formation and choroidal neovascularization. We used stable isotope labeling by amino acids in cell culture (SILAC) in combination with LC-MS/MS analysis and ZoomQuant quantification to assess differential protein secretion by RPE cell cultures prepared from human autopsy eyes of AMD donors (diagnosed by histological examinations of the macula and genotyped for the Y402H-complement factor H variant) and age-matched healthy control donors. In general, RPE cells were found to secrete a variety of extracellular matrix proteins, complement factors, and protease inhibitors that have been reported to be major constituents of drusen (hallmark deposits in AMD). Interestingly, RPE cells from AMD donors secreted 2 to 3-fold more galectin 3 binding protein, fibronectin, clusterin, matrix metalloproteinase-2 and pigment epithelium derived factor than RPE cells from age-matched healthy donors. Conversely, secreted protein acidic and rich in cysteine (SPARC) was found to be down regulated by 2-fold in AMD RPE cells versus healthy RPE cells. Ingenuity pathway analysis grouped these differentially secreted proteins into two groups; those involved in tissue development and angiogenesis and those involved in complement regulation and protein aggregation such as clusterin. Overall, these data strongly suggest that RPE cells are involved in the biogenesis of drusen and the pathology of AMD.     

Advances in the neural bases of orientation and navigation

The ability to locomote in one direction (oriented movement),and the ability to navigate toward a distant goal are relatedbehaviors that are phylogenetically widespread. Orientationbehaviors include finding the source of an odor or acousticsignal, using a sun-compass for guidance, and moving relativeto fluid-dynamic cues. Such abilities might require little morethan directionally selective sensors coupled to a turning mechanism.This type of behavior, therefore, can be implemented by relativelysimple circuits. In contrast, navigation involves both the abilityto detect direction, as well as a map-sense that provides position.Navigation is less common and arguably requires greater braincomputation than does simple orientation, but may be presentin arthropods as well as in vertebrates. Great progress hasbeen made in exploring the biophysical and sensory bases forthese behaviors, and in recent years the locations and the identityof the cellular transducers of the sensory stimuli (for example,geomagnetic fields) have been narrowed in some taxa. Similarly,neurons within the central nervous that most likely functionin higher order computational processes have been identified.For example, direction-selective and position-responsive braincells have been located in the brains of mammals and birds,and these cells might contribute to a cognitive map that canenable navigation. One model organism in which orientation andnavigation has been extensively studied is the sea slug Tritoniadiomedea. This animal orients its crawling to chemical, hydrodynamic,and geomagnetic cues. The brain of Tritonia has 7000 relativelylarge neurons that facilitate circuit analysis. Recent workhas characterized both peripheral and central neural correlatesof orientation signals, as well as the control of thrust andturning, and studies of their field behavior have suggestedhow these disparate orientation systems may be integrated. Thesefindings provide the basis for future studies to determine howthe nervous system combines multiple sensory cues into a complexhierarchy of signals that can direct motor output and thereforeguide navigational tasks.     

Role of Lysyl Oxidase Propeptide in Secretion and Enzyme Activity

Lysyl oxidase (LOX) is secreted as a proenzyme (proLOX) that is proteolytically processed in the extracellular milieu to release the propeptide and mature, active LOX. LOX oxidizes lysyl residues of a number of protein substrates in the extracellular matrix and on the cell surface, which impacts several physiological and disease states. Although the LOX propeptide (LOX‐PP) is glycosylated, little is known about the role of this modification in LOX secretion and activity. To gain insight into this issue, cells were transfected with native, full‐length LOX cDNA (pre‐pro‐LOX), the N‐glycosylation null pre‐[N/Q]pro‐LOX cDNA and the deletion mutant pre‐LOX cDNA, referred to as secretory LOX, in which mature LOX is targeted to the secretory pathway without its N‐terminal propeptide sequence. The results show that glycosylation of the LOX‐PP is not required for secretion and extracellular processing of pro‐LOX but it is required for optimal enzyme activity of the resulting mature LOX. Complete deletion of the propeptide sequence prevents mature LOX from exiting the endoplasmic reticulum (ER). Taken together, our study points out the requirement of the LOX‐PP for pro‐LOX exit from the ER and is the first to highlight the influence of LOX‐PP glycosylation on LOX enzyme activity. J. Cell. Biochem. 111: 1231–1243, 2010. © 2010 Wiley‐Liss, Inc.     

Fusion-Deficient Insertion Mutants of Herpes Simplex Virus Type 1 Glycoprotein B Adopt the Trimeric Postfusion Conformation

Glycoprotein B (gB) enables the fusion of viral and cell membranes during entry of herpesviruses. However, gB alone is insufficient for membrane fusion; the gH/gL heterodimer is also required. The crystal structure of the herpes simplex virus type 1 (HSV-1) gB ectodomain, gB730, has demonstrated similarities between gB and other viral fusion proteins, leading to the hypothesis that gB is a fusogen, presumably directly involved in bringing the membranes together by refolding from its initial or prefusion form to its final or postfusion form. The only available crystal structure likely represents the postfusion form of gB; the prefusion form has not yet been determined. Previously, a panel of HSV-1 gB mutants was generated by using random 5-amino-acid-linker insertion mutagenesis. Several mutants were unable to mediate cell-cell fusion despite being expressed on the cell surface. Mapping of the insertion sites onto the crystal structure of gB730 suggested that several insertions might not be accommodated in the postfusion form. Thus, we hypothesized that some insertion mutants were nonfunctional due to being “trapped” in a prefusion form. Here, we generated five insertion mutants as soluble ectodomains and characterized them biochemically. We show that the ectodomains of all five mutants assume conformations similar to that of the wild-type gB730. Four mutants have biochemical properties and overall structures that are indistinguishable from those of the wild-type gB730. We conclude that these mutants undergo only minor local conformational changes to relieve the steric strain resulting from the presence of 5 extra amino acids. Interestingly, one mutant, while able to adopt the overall postfusion structure, displays significant conformational differences in the vicinity of fusion loops, relative to wild-type gB730. Moreover, this mutant has a diminished ability to associate with liposomes, suggesting that the fusion loops in this mutant have decreased functional activity. We propose that these insertions cause a fusion-deficient phenotype not by preventing conversion of gB to a postfusion-like conformation but rather by interfering with other gB functions.Herpes simplex virus type 1 (HSV-1) is the prototype of the diverse herpesvirus family that includes many notable human pathogens (26). In addition to the icosahedral capsid and the tegument that surround its double-stranded DNA genome, herpesviruses have an envelope—an outer lipid bilayer—bearing a number of surface glycoproteins. During infection, HSV-1 must fuse its envelope with a cellular membrane in order to deliver the capsid into a target host cell. Among its viral glycoproteins, only glycoprotein C (gC), gB, gD, gH, and gL participate in this entry process, and only the last four are required for fusion (28). Although gD is found only in alphaherpesviruses, all herpesviruses encode gB, gH, and gL, which constitute their core fusion machinery. Of these three proteins, gB is the most highly conserved.We recently determined the crystal structure of a nearly full-length ectodomain of HSV-1 gB, gB730 (18). The crystal structure of the ectodomain of gB from Epstein-Barr virus, another herpesvirus, has also been subsequently determined (4). The two structures showed similarities between gB and other viral fusion proteins, in particular, G from an unrelated vesicular stomatitis virus (VSV) (25), leading to the hypothesis that gB is a fusogen, presumably directly involved in bringing the viral and host cell membranes together to enable their fusion. However, gB alone is known to be insufficient for membrane fusion; the gH/gL heterodimer is also required. This insufficiency raises the question of exactly how gB functions during viral entry. Answering this question is critical for understanding the complex mechanism that herpesviruses use to enter their host cells.In acting as a viral fusogen, gB must undergo dramatic conformational changes, refolding through a series of conformational intermediates from its initial, or prefusion form, to its final, or postfusion form (15). These conformational changes are not only necessary to bring the two membranes into proximity; they are also thought to provide the energy for the fusion process. The prefusion form corresponds to the protein present on the viral surface prior to initiation of fusion. The postfusion form represents the protein after fusion of the viral and host cell membranes. The available gB structure likely represents its postfusion form, since it shares more in common with the postfusion rather than the prefusion structure of vesicular stomatitis virus (VSV) G (3, 17). However, the prefusion form has not yet been characterized.Recently, a panel of gB mutants was generated by using random linker-insertion mutagenesis (21). Of these mutants, 16 were particularly interesting because they were nonfunctional in cell-cell fusion assays despite being expressed on the cell surface at levels that indicate proper folding for transport. These observations suggested that each insertion somehow interfered with gB function. Insertions in 12 of these mutants are located within the available structure of the gB ectodomain, which allowed Lin and Spear to analyze their locations (21).The most prominent examples of such nonfunctional mutants are two mutants with insertions after residues I185 or E187, henceforth referred to as “cavity mutants” because both I185 and E187 point into a cavity inside the gB trimer (Fig. 1B and D). Although this cavity might accommodate a single 5-amino-acid insertion, it “is not large enough to accommodate three 5-amino-acid insertions” (21) that would be present in the trimer (one insertion per protomer).Open in a separate windowFIG. 1.Location of the insertion sites in the sequence of gB and the structure of the postfusion form of its ectodomain. (A) Linear diagram of the full-length gB with functional domains highlighted (as in reference 18). Domain I is shown in cyan, domain II in green, domain III in yellow, domain IV in orange, domain V in red, and the disordered region between domains II and III in purple. Regions absent from the crystal structure of gB730 are shown in gray. Sequences in the region of 5-amino-acid insertions (residues 181 to 190 and residues 661 to 680) are shown in black. Arrows mark the locations of 5-amino-acid insertions, shown as red text. (B) Crystal structure of gB730 (18). Residues preceding the 5-amino-acid insertions in mutants studied here are shown as spheres colored by domain, consistent with panel A. Boxes delineate the hinge region, enlarged in panel C, and the cavity region, enlarged in panel D. (C) Close-up view of the hinge region shown in molecular surface representation, with residues 663 to 675 displayed as sticks. Hydrophobic residues are colored orange. Residues preceding the 5-amino-acid insertions in mutants studied here are labeled with asterisks; remaining labels correspond to additional hydrophobic residues in the 663-675 region. (D) Enlarged view of the cavity region. Residues that line the cavity and are not solvent exposed are colored magenta. Residue E187 of each protomer is colored teal and shown as spheres. Fusion loops for two protomers are marked with asterisks; the third pair of fusion loops lies behind the crystal structure and is not visible. Panels B, C, and D were made by using Pymol (http://www.pymol.org/).Five other nonfunctional mutants have insertions after residues D663, T665, V667, I671, or L673, respectively. We refer to them as “hinge mutants.” These residues lie in the region located between domains IV and V, which has been termed the hinge region because it may play an important role during the conformational transition from the prefusion to the postfusion form (17). Lin and Spear proposed that insertions following these residues “would likely affect hinge regions” (21), with the implication that they may prevent gB from refolding into the postfusion conformation. Our analysis suggested that insertions after these residues could, perhaps, be sterically accommodated in the structure but would probably be energetically unfavorable by causing several buried hydrophobic side chains in the 665-673 region, such as F670, I671, and L673, to become exposed (Fig. 1B and C).In light of these observations, we hypothesized that the insertion mutants are “trapped” in a prefusion form. We decided to test this hypothesis by determining whether the ectodomain of gB containing one of these insertion mutations is able to assume the conformation seen in the crystal structure of the wild-type gB ectodomain, which we are referring to as the likely postfusion conformation. For this purpose, we chose one cavity mutant, containing an insertion after E187, and four hinge mutants, containing insertions after T665, V667, I671, or L673, respectively. We chose to test four hinge mutants because structure analysis suggested to us that insertions following the respective residues might not affect the structure in precisely the same way. We expressed the soluble ectodomain of each mutant by using a baculovirus expression system and characterized the purified proteins by using biochemical and biophysical methods. Surprisingly, we found that the ectodomains of all five mutants assume a conformation similar to that of the wild-type gB ectodomain. The four hinge mutants had biochemical properties and overall three-dimensional structures that were indistinguishable from those of the wild-type gB ectodomain. We conclude that these mutants undergo only minor local conformational changes to relieve the steric strain resulting from the presence of 5 extra amino acids. Interestingly, the cavity mutant, while able to adopt the overall postfusion structure, still displayed significant conformational differences relative to wild-type gB. Because these conformational differences are in the vicinity of fusion loops, we conclude that the fusion loops in this mutant have decreased functional activity.     

p38 MAP Kinase and MAPKAP Kinases MK2/3 Cooperatively Phosphorylate Epithelial Keratins

The MAPK-activated protein kinases (MAPKAP kinases) MK2 and MK3 are directly activated via p38 MAPK phosphorylation, stabilize p38 by complex formation, and contribute to the stress response. The list of substrates of MK2/3 is increasing steadily. We applied a phosphoproteomics approach to compare protein phosphorylation in MK2/3-deficient cells rescued or not by ectopic expression of MK2. In addition to differences in phosphorylation of the known substrates of MK2, HSPB1 and Bag-2, we identified strong differences in phosphorylation of keratin 8 (K8). The phosphorylation of K8-Ser⁷³ is catalyzed directly by p38, which in turn shows MK2-dependent expression. Notably, analysis of small molecule p38 inhibitors on K8-Ser⁷³ phosphorylation also demonstrated reduced phosphorylations of keratins K18-Ser⁵² and K20-Ser¹³ but not of K8-Ser⁴³¹ or K18-Ser³³. Interestingly, K18-Ser⁵² and K20-Ser¹³ are not directly phosphorylated by p38 in vitro, but by MK2. Furthermore, anisomycin-stimulated phosphorylations of K20-Ser¹³ and K18-Ser⁵² are inhibited by small molecule inhibitors of both p38 and MK2. MK2 knockdown in HT29 cells leads to reduced K20-Ser¹³ phosphorylation, which further supports the notion that MK2 is responsible for K20 phosphorylation in vivo. Physiologic relevance of these findings was confirmed by differences of K20-Ser¹³ phosphorylation between the ileum of wild-type and MK2/3-deficient mice and by demonstrating p38- and MK2-dependent mucin secretion of HT29 cells. Therefore, MK2 and p38 MAPK function in concert to phosphorylate K8, K18, and K20 in intestinal epithelia.