Transforming growth factor-beta1 is the predominant isoform required for breast cancer cell outgrowth in bone.

Transforming growth factor (TGF)-beta signaling is a potent modulator of the invasive and metastatic behavior of breast cancer cells. Indeed, breast tumor responsiveness to TGF-beta is important for the development of osteolytic bone metastases. However, the specific TGF-beta isoforms that promote breast cancer outgrowth in bone is unknown. We demonstrate that expression of a TGF-beta ligand trap, which neutralizes TGF-beta1 and TGF-beta3, in MDA-MB-231 breast cancer cells diminished their outgrowth in bone and reduced the severity of osteolytic lesion formation when compared with controls. We further show that a reduction or loss of TGF-beta1 expression within the bone microenvironment of TGF-beta1+/- and TGF-beta1-/- mice significantly reduced the incidence of breast tumor outgrowth compared with wild-type animals. Interestingly, those tumors capable of growing within the tibiae of TGF-beta1-deficient mice had upregulated expression of all three TGF-beta isoforms. Finally, breast cancer cells expressing the TGF-beta ligand trap showed a pronounced reduction in their ability to form osteolytic lesions when injected into the tibiae of TGF-beta1+/- mice. Thus, our studies show that both host- and tumor-derived TGF-beta expression plays a critical role during the establishment and outgrowth of breast cancer cells in bone.

Transforming growth factor (TGF)-beta 1 internalization: modulation by ligand interaction with TGF-beta receptors types I and II and a mechanism that is distinct from clathrin-mediated endocytosis.

Transforming growth factor-beta (TGF-beta) internalization was studied by monitoring the uptake of (125)I-TGF-beta1 in Mv1Lu cells, which endogenously express TGF-beta receptors types I (RI), II (RII), and III (RIII), and 293 cells transfected with RI and RII. At 37 degrees C internalization occurred rapidly, within 10 min of ligand addition. Internalization was optimal in 293 cells expressing both RI and RII. Internalization was prevented by phenylarsine oxide, a nonspecific inhibitor of receptor internalization, but was not affected by reagents that interfere with clathrin-mediated endocytosis such as monodansylcadaverine, K44A dynamin, and inhibitors of endosomal acidification. Electron microscopic examination of Mv1Lu cells treated with (125)I- TGF-beta1 at 37 degrees C indicated that internalization occurred via a noncoated vesicular mechanism. Internalization was prevented by prebinding cells with TGF-beta1 at 4 degrees C for 2 h prior to switching the cells to 37 degrees C. This was attributed to a loss of receptor binding, as indicated by a rapid decrease in the amount of TGF-beta1 bound to the cell surface at 37 degrees C and by a reduction in the labeling intensities of RI and RII in (125)I-TGF-beta1-cross-linking experiments. Mv1Lu or 293 (RI+RII) cells, prebound with TGF-beta1 at 4 degrees C and subsequently stripped of ligand by an acid wash, nevertheless initiated a signaling response upon transfer to 37 degrees C, suggesting that prebinding promotes formation of stable RI.RII complexes that can signal independently of ligand.

Predominant intracellular localization of the type I transforming growth factor-beta receptor and increased nuclear accumulation after growth arrest.

Transforming growth factor-beta (TGF-beta) signaling requires the functional interaction of two distinct receptors, type I (RI) and type II (RII), at the cell surface. Exposure of cells to TGF-beta results in receptor internalization and down-regulation (Zwaagstra et al., 1999, Exp. Cell Res. 252, 352362); however, little is known about the subsequent fate of RI or RII. In this study the cellular distribution of RI was examined in cells before and after treatment with ligand. RI was localized by immunocytochemistry and confocal microscopy using two polyclonal antisera directed against two different epitopes, one in the C-terminal region and one in the N-terminal region of the cytoplasmic domain. The majority of RI molecules in untreated MvlLu and A549 cells were found to be intracellular. Treatment of MvlLu and A549 cells with 100 pM TGF-beta1 for 24 h at 37 degrees C caused a redistribution of surface RI on MvlLu cells, as evidenced by surface RI aggregation. Unexpectedly, this TGF-beta1 treatment also caused redistribution and accumulation of intracellular RI in and around the nucleus for both MvlLu and A549 cells. Nuclear accumulation of RI was also promoted independently of ligand receptor activation by treatment of MvlLu cells with olomoucine, an agent that results in growth arrest. The capacity of RI to localize in the nucleus was confirmed by microscopic examination of 293 cells transiently expressing RI fused to green fluorescent protein (RI-GFP). Olomoucine treatment of these cells resulted in the movement of RI-GFP into the nucleus. Our results indicate that growth arrest alters intracellular transport/routing of RI and may indicate that RI functions not only at the cell surface but inside the cell as well.

Down-regulation of transforming growth factor-beta receptors: cooperativity between the types I, II, and III receptors and modulation at the cell surface.

The types I, II, and III receptors (RI, RII, RIII) for transforming growth factor-beta (TGF-beta) become down-regulated in response to ligand, presumably via their internalization from the cell surface. This report examines the down-regulation of full-length RI, RII, and RIII in cells endogenously or transiently expressing these receptors. Down-regulation occurred rapidly (within 2 h after TGF-beta1 treatment at 37 degrees C) and showed a dose response, between 10 and 200 pM TGF-beta1, in cells expressing RI, RII, and RIII (Mv1lu and A549 cells). A comparison between Mv1Lu and mutant cell derivatives R-1B (lacking RI) or DR-26 (lacking RII) indicated that all three receptors were necessary for efficient down-regulation. Down-regulation experiments, utilizing TGF-beta-treated 293 cells transiently expressing different combinations of these receptors indicated that neither RII or RIII were down-regulated when expressed alone and that RI was required for maximal down-regulation of RII. RII and RIII were partially down-regulated when these receptors were coexpressed in the absence of RI (in R-1B and 293 cells). Surprisingly, TGF-beta receptors were partially down-regulated in Mv1Lu, A549, and 293 cells treated with TGF-beta1 at 4 degrees C. Microscopic examination of 293 cells coexpressing RI fused to green fluorescent protein (RI-GFP) and RII indicated that, after treatment with TGF-beta1 at 4 degrees C, RI-GFP formed aggregates at the cell surface at this temperature. RI-GFP was not detected at the surface of these cells after TGF-beta1 treatment at 37 degrees C. Our results suggest a two phase mechanism for TGF-beta1 receptor down-regulation involving receptor modulation (aggregation) at the cell surface and internalization.

Similarities in regulation of the HSV-1 LAT promoter in corneal and neuronal cells.

PURPOSE: To address the possibility of neuronal-like herpes simplex virus type 1 (HSV-1) latency in the cornea by determining if regulation of the HSV-1 LAT promoter in stromal keratocytes is similar to LAT promoter regulation in neurons. METHODS: Transient chloramphenicol acetyltransferase (CAT) assays were used to measure the relative promoter activity of various HSV-1 LAT promoter fragments in primary human corneal cells versus neuronal and nonneuronal cells. RESULTS: The authors found that the LAT promoter, whose location they previously mapped in neurons using transient CAT assays, functioned in stromal keratocytes using the same assay system and that two regions between -283 and -1932 nucleotides relative (upstream) to the start of LAT transcription slightly increased the LAT promoter activity in stromal keratocytes. They previously showed a similar increase in neuronal cells, and a large decrease in nonneuronal cells. In addition, they found that a neuronal specific enhancer region they previously defined between -162 and -283 nucleotides upstream of the start of LAT transcription also enhanced promoter activity in stromal keratocytes. Using gel-shift assays, they detected a nuclear factor specific to neurons and stromal keratocytes that binds to the LAT promoter and that may be a LAT regulatory factor. CONCLUSIONS: Recently, it has been suggested that the cornea might serve as an alternative site of latent herpes simplex virus type 1 (HSV-1) infection. However, this remains controversial. The authors' findings suggest that corneal and neuronal cells regulate the LAT promoter similarly and that this regulation differs from that seen in nonneuronal cells. Thus, the possibility of neuronal-like latency in the cornea remains plausible.

Type VIII adenylyl cyclase. A Ca2+/calmodulin-stimulated enzyme expressed in discrete regions of rat brain.

A cDNA that encodes type VIII adenylyl cyclase has been isolated from two rat brain libraries. The open reading frame encodes a 1248-amino acid protein predicted to have two sets of six transmembrane spans and two putative nucleotide binding domains as is characteristic of other mammalian adenylyl cyclases. Two type VIII messages are detected in rat brain with estimated sizes of 5.5 and 4.4 kilobases. In situ hybridization indicates that the type VIII messages are most abundantly expressed in the granule cells of the dentate gyrus, the pyramidal cells of hippocampal fields CA1-CA3, the entorhinal cortex, and the piriform cortex. Hybridization is also detected in the neocortex, the amygdaloid complex, and regions of the thalamus and hypothalamus. Stable expression of the type VIII cDNA in human embryonal kidney cells leads to the appearance of a novel 165-kDa glycoprotein in the membrane fraction. Stimulation of these cells with agents that increase intracellular Ca2+ results in up to 43-fold increases in cAMP accumulation over that of control cells transfected with the expression vector. Addition of isoproterenol alone does not lead to type VIII-specific effects in intact cells. Adenylyl cyclase activity in membranes prepared from type VIII-transformed cells is stimulated up to 40-fold by the addition of Ca2+/calmodulin (EC50 = 53 nM calmodulin). The addition of activated recombinant alpha subunit of Gs synergistically increases the Ca2+/calmodulin-stimulated activity. A possible role for type VIII adenylyl cyclase in long-term potentiation is discussed.

Molecular diversity in the adenylylcyclase family. Evidence for eight forms of the enzyme and cloning of type VI.

The conservation of amino acid sequence among types I-IV adenylylcyclase has made it possible to apply the polymerase chain reaction to examine the extent of the molecular diversity within this family of enzymes. cDNA templates from rat heart, liver, kidney, guinea pig brain and testes, and mouse skeletal muscle were amplified with primers specific to adenylylcyclase sequences. Evidence was obtained for a total of eight distinct gene products divisible into five subfamilies. Five of the products correspond to regions from cloned forms of adenylylcyclase, while three are previously unidentified. As many as seven different adenylylcyclases are expressed in rat heart, liver, and kidney based on this analysis. Two newly identified polymerase chain reaction (PCR) products were utilized to screen a rat cDNA library from H35 Reuber hepatoma cells. A 6080-nucleotide cDNA contains an open reading frame encoding the 1166-amino acid type VI protein which has a predicted topography similar to that of other adenylylcyclases. The type VI message is abundantly expressed in rat heart, kidney, and brain. Human embryonal kidney cells stably expressing the cDNA showed an enhanced response to isoproterenol that could be inhibited by carbachol in intact cells. Increases in intracellular Ca2+ contribute to the inhibitory effect of carbachol.

Identification of a major regulatory sequence in the latency associated transcript (LAT) promoter of herpes simplex virus type 1 (HSV-1).

The latency associated transcript (LAT) gene is the only viral genomic region that is abundantly transcribed during herpes simplex virus type 1 (HSV-1) neuronal latency. As such, it may play an important role in HSV-1 latency and/or reactivation. The regulation of the LAT gene is complex and appears to include a combination of positive and negative functional elements in and near the LAT promoter. In this study, transient CAT assays were used to map the minimal promoter necessary for constitutive activity in neuronal and nonneuronal cells to between nucleotide positions -161 and -2 (relative to the start of LAT transcription). The region from -283 to -161 was able to slightly increase promoter activity of the minimal promoter and appeared to have a larger effect in neuronal derived cells. Gel-shift experiments using nuclear extracts from neuronal and nonneuronal derived cells detected a major factor that bound specifically to the -161 to -2 probe. We designated this factor LAT promoter binding factor (LPBF). Two additional minor factors also bound specifically to the minimal promoter. DNase I footprint analysis and gel-shift competition experiments demonstrated that LPBF bound to a region that includes the palindromic sequence CCACGTGG located at nucleotides -72 to -65. Deletion of this palindrome resulted in a loss of binding of LPBF from the minimal promoter region and an 8- to 30-fold reduction in promoter activity in both neuronal and nonneuronal cells. Thus, LPBF appears to play a major role in LAT promoter regulation.

Activity of herpes simplex virus type 1 latency-associated transcript (LAT) promoter in neuron-derived cells: evidence for neuron specificity and for a large LAT transcript.

By using chloramphenicol acetyltransferase (CAT) assays in neuron-derived cell lines, we show here that promoter activity associated with the herpes simplex virus type 1 latency-associated transcript (LAT) had neuronal specificity. Promoter activity in these transient CAT assays coincided with a DNA region containing excellent RNA polymerase II promoter consensus sequences. Primer extension analysis in a LAT promoter-CAT plasmid construct placed the start of transcription about 28 nucleotides from the first T in the consensus TATA box sequence. Neuronal specificity of this promoter was suggested by examining the effect of sequences upstream of the promoter on CAT activity in neuronal versus nonneuronal cells. In nonneuronal cells, promoter activity was decreased 3- to 12-fold with the addition of upstream sequences. In contrast, in neuron-derived cells, the addition of upstream sequences did not decrease promoter activity. The LAT promoter predicted by our transient CAT assays was located over 660 nucleotides upstream from the 5' end of the previously mapped 2-kilobase (kb) LAT. This unusual location was explained by in situ and Northern (RNA) blot hybridization analyses that suggested that LAT transcription began near the promoter detected in our CAT assays, rather than near the 5' end of the 2-kb LAT. In situ hybridization with neurons from latently infected rabbits detected small amounts of LAT RNA within 30 nucleotides of the consensus TATA box sequence. This suggested that LAT transcription began near this TATA box. Northern blot hybridization of RNA from ganglia of latently infected rabbits revealed a faint 8.3-kb band of the same sense as LAT. We conclude that (i) the LAT promoter has neuronal specificity, (ii) the LAT promoter is located over 660 nucleotides upstream of the 5' end of the previously characterized stable 2-kb LAT, (iii) LAT transcription begins about 28 nucleotides from the first T of the consensus TATA box sequence and extends to near the first available polyadenylation site approximately 8.3 kb away, and (iv) this 8.3-kb RNA may be an unstable precursor of the more stable 2- and 1.3-kb LATs.

The use of lectin affinity columns for selection of precursor or fully glycosylated forms of glycoprotein gD1 of herpes simplex virus type 1.

Several lectins were examined for their ability to bind to the glycoprotein gD1 polypeptide from Vero cells infected by herpes simplex virus type 1 (HVS-1), strain KOS. At least four distinct forms of gD1 (1, 2, 3 and 4), ranging in size from 59K to 52K, were resolved by SDS-10% polyacrylamide gel electrophoresis. Wheat germ agglutinin (WGA) did not bind to any of these forms, suggesting that if any sialic residues are present in the carbohydrate moieties of gD1, they are not available for binding to WGA. The entire population of forms 1 and 2 (approximately 59K) bound to castor bean-120 (CB-120) lectin affinity columns, suggesting the presence of terminal galactose residues on the mature and more fully glycosylated carbohydrate moieties of gD1. The forms 3 and 4, representing precursor gD1 molecules, did not bind. The majority of forms 2 and 4, and a portion of form 3 bound to lentil lectin, suggesting the presence of fucose and alpha-linked mannosyl residues on these molecules. A gD1-specific, high molecular weight species (120-125K) was detected in the lentil lectin-binding fraction but not in the fraction bound to CB-120 lectin or in the original infected-cell extract. The results indicated that lectin affinity chromatography, using lentil and CB-120 lectins, is useful as an initial step for the selection and purification of the individual glycosylated forms of gD1.

The nucleotide sequence of herpes simplex virus type 2 (333) glycoprotein gB2 and analysis of predicted antigenic sites.

The gene coding for glycoprotein B2 (gB2) of herpes simplex virus type 2 (HSV-2) strain 333 was mapped and its nucleotide sequence determined. Open reading frame analysis deduced a polypeptide consisting of 902 amino acids and having close homology to gB1 of HSV type 1. Several predicted features of gB2 are consistent with a membrane-bound glycoprotein, i.e., a signal peptide sequence, a hydrophilic extracellular domain containing possible N-linked glycosylation sites, a hydrophobic membrane spanning sequence, and a cytoplasmic domain. Computer analysis on hydrophilicity, accessibility, and flexibility of the gB2 amino acid sequence, produced a composite surface value plot. At least nine major antigenic regions were predicted on the extracellular domain. The amino acids between residues 59-74, 127-139, 199-205, 460-476, and 580-594 exhibited the highest surface values. Comparison of the primary sequence with gB1 revealed localized regions showing amino acid diversity. Several of these locations correspond to major antigenic regions. Chou and Fasman analyses indicated that the amino acid substitutions, between positions 57-66, 461-472, and 473-481, induced changes in the secondary structure of gB. These sites could represent site-specific epitopes in the gB polypeptide.