key: cord-0971775-uxltqopq
authors: Rosati, A; Graziano, V; De Laurenzi, V; Pascale, M; Turco, M C
title: BAG3: a multifaceted protein that regulates major cell pathways
date: 2011-04-07
journal: Cell Death Dis
DOI: 10.1038/cddis.2011.24
sha: ca8b14f351edca29473646f4bb9669c3ad03500c
doc_id: 971775
cord_uid: uxltqopq

Bcl2-associated athanogene 3 (BAG3) protein is a member of BAG family of co-chaperones that interacts with the ATPase domain of the heat shock protein (Hsp) 70 through BAG domain (110–124 amino acids). BAG3 is the only member of the family to be induced by stressful stimuli, mainly through the activity of heat shock factor 1 on bag3 gene promoter. In addition to the BAG domain, BAG3 contains also a WW domain and a proline-rich (PXXP) repeat, that mediate binding to partners different from Hsp70. These multifaceted interactions underlie BAG3 ability to modulate major biological processes, that is, apoptosis, development, cytoskeleton organization and autophagy, thereby mediating cell adaptive responses to stressful stimuli. In normal cells, BAG3 is constitutively present in a very few cell types, including cardiomyocytes and skeletal muscle cells, in which the protein appears to contribute to cell resistance to mechanical stress. A growing body of evidence indicate that BAG3 is instead expressed in several tumor types. In different tumor contexts, BAG3 protein was reported to sustain cell survival, resistance to therapy, and/or motility and metastatization. In some tumor types, down-modulation of BAG3 levels was shown, as a proof-of-principle, to inhibit neoplastic cell growth in animal models. This review attempts to outline the emerging mechanisms that can underlie some of the biological activities of the protein, focusing on implications in tumor progression.

Bcl2-associated athanogene (BAG) proteins are a family of co-chaperones that interact with the ATPase domain of the heat shock protein (Hsp) 70 through a specific structural domain known as BAG domain (110-124 amino acids). 1, 2 Members of the family are found throughout the evolution in yeast (Saccharomyces cerevisiae, Schizosaccharomyces pombe), invertebrates (Caenorhabditis elegans, Ciona intestinalis, Drosophila), amphibians (Xenopus laevis), mammals (humans, mice) and plants (Oryza sativa, Arabidopsis thaliana), 1,3-6 suggesting a fundamental biological role. BAG3 was originally identified by yeast two-hybrid screening using the ATPase domain of the Hsp (heat shock cognate (Hsc)/Hsp) 70 as a bait. 1 In addition to the BAG domain, BAG3 contains a WW domain and a proline-rich repeat (PXXP; Figure 1a ) that mediate binding to other partners. 1, 7, 8 Here we will outline the roles so far identified of BAG3 in the regulation of major biological processes, that is, apoptosis, development, cytoskeleton organization and autophagy. By modulating these pathways, BAG3 appears to mediate cell adaptive responses to stressful stimuli, and its alterations result in altered homeostasis and reduced cytoprotection, explaining why its expression is often found deregulated in a vast series of tumors.

Two BAG3 forms have been described so far: one is the full-lenght product of the bag3 gene having an apparent mass of 74 kDa, the other one is a shorter BAG3 protein found in association to neuronal synaptosomes 2, [9] [10] [11] (Figure 1b) . The BAG3 full-length protein is localized in the cytoplasm, mainly concentrated in the rough endoplasmic reticulum; on cell exposure to stressors, a slightly different molecular weight variant of this form can also be observed, and both co-exist in some cell types and run as a doublet in a standard western blot. The origin of this doublet is currently unknown, but it could derive from post-translational modifications as phosphorylations, indeed BAG3 protein contains several serinerich motifs and 10 tyrosine residues. Tyrosine phosphorylation of BAG3 occurs on EGF stimulation in human breast cancer cell lines. 12 This post-translational variant of BAG3 protein appears also to be associated to Bruton's tyrosine kinase (Btk) protein in Defew cells on oxidative stress induction. 13 Recently, a shorter form of BAG3 (40 kDa) has been characterized by immunoprecipitation from neural synaptosomes homogenates and successive mass spectrometry, 11 again it is yet unknown whether this form derives from the alternative splicing or proteolytic processing. BAG3 expression has also been observed in the nuclei of some cell types, including pancreatic carcinoma cells (unpublished results from our laboratory). Interestingly, BAG3 was shown to localize in nuclei of cells infected by some viruses; those findings suggest an involvement of BAG3 in viral expression and/or replication, and indeed some reports indicate a requirement for BAG3 for virus gene expression and/or viral progeny production. 12, [14] [15] [16] [17] [18] In keeping with those results, viral infection was shown to induce the expression of BAG3, as a possible tool contributing to virus life cycle. 12, 19 In humans, bag3 gene expression is constitutive in myocytes, a few other normal cell types and several primary tumors or tumor cell lines (lymphoid or myeloid leukemias, lymphomas, myeloma, neuroblastoma, pancreas, thyroid, breast and prostate carcinomas, melanoma, osteosarcoma, kidney, colon and ovary cancers, glioblastoma). [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] [37] It is instead induced in different normal cell types (leukocytes, epithelial and glial cells, retinal cells) by a variety of stressors, such as oxidants, high temperature, serum deprivation, heavy metals, HIV-1 infection, ELF exposure, electrophile stress, hemodialysis treatment, pulsed ultrasound, retinal light damage, kanaic acid-induced seizure and transient forebrain ischemia. 2, 10, 14, 19, 35, [37] [38] [39] [40] [41] [42] [43] [44] The expression of stress-responsive genes is regulated by the heat shock transcription factors (HSFs), 45 including HSF1, that is required for tumor initiation and maintenance in a variety of cancer models. 46 bag3 gene promoter activity is regulated by HSF1, 31, 47, 48 again suggesting a role in tumor formation. Other known transcription factors that are known to regulate bag3 expression are Egr1 29 AibZIP 26 and WT1. 49 The regulation by WT1 is of particular interest because of the role played by this transcription factor in human leukemias 50 (see the section BAG3 in leukemias). Furthermore, in some cell types bag3 expression seems to be controlled by its own product. 51 A number of drugs -proteasome inhibitors, TNF-related apoptosis-inducing ligand, fludarabine, cytosine arabinoside and etoposide -increase BAG3 protein levels, this in turn contributes to cell resistance to therapy, and indeed bag3 silencing improves neoplastic cell apoptotic response to drugs. 21, 22, 24, 30, 37, 52, 53 

In some cell types, bag3 expression appears to be developmentally regulated. In the developing central nervous system (CNS) of a rat, there is a transient expression, detectable by immunohistochemistry, of BAG3 in the cerebral cortex and hippocampus, whereas a considerable expression is maintained in the rostral migratory stream and the subventricular zone of the lateral ventricle; there is an abrupt increase of BAG3-positive neurons in the cortex and hippocampus during the first postnatal week, which declines thereafter. Two specific populations of BAG3-positive neurons can be identified in the developing forebrain of a rat. 54 Furthermore, recent results indicated that BAG3 is expressed in neural progenitors and sustains proliferation, mainly in response to FGF2, in those cells. 55 In addition, an early transient expression of BAG3 was observed in midline radial glia in the developing brainstem and spinal cord of a rat. 56 Together, these pieces of evidence indicate a role for BAG3 in the development of both the neuronal and glial components of central nervous system. In agreement with the hypothesis of BAG3 involvement in CNS development, an altered BAG3 expression was observed in the cerebellum of hypothyroid juvenile mice, and was suggested to contribute to impaired development of the hypothyroid brain. Moreover, in rat and human cardiomyocytes, BAG3 protein appears to be expressed during differentiation from cardiomyoblasts and to sustain myogenin expression. 57 These findings indicate an involvement of BAG3 protein in late heart development and are in keeping with the role of BAG3 in the survival and myofibrillar integrity in cardiocytes and, in general, in muscle cells. Indeed, mice with homozygous disruption of bag3 gene develop post birth an early fulminant myopathy 23 and, in humans, a heterozygous p.Pro209Leu mutation in BAG3 protein was recently recognized to be responsible for a severe muscular dystrophy with cardiomyopathy and severe respiratory insufficiency. [57] [58] [59] In one of the three studied families carrying this mutation, an axonal neuropathy was also present. This observation is intriguing in view of the reported localization of a 40 kD form of BAG3 in synaptosomes 11 and of the above discussed role of BAG3 in CNS. Finally, a recent paper reports a role of BAG3 in the development of the hematopoietic system, showing that mice with a targeted disruption of bag3 exhibit a loss of hematopoietic stem cells and defective B-cell development, because of the microenvironmental defect, that is, an alteration in the vascular stem cell niche. 60 The authors observed a defective growth of stromal progenitor cells in colony-forming unit fibroblasts, a defect in sinusoidal endothelium, and the loss of stromal cells expressing CXCL-12 or IL-7 in the bone marrow. 60 The molecular mechanisms underlying those perturbations could, once identified, disclose novel prospects in the understanding of the hematopoietic process. Last but not least, recent evidence indicate that BAG3 is also implicated in regulating the general metabolic state of the organism, as bag3-deficient mice were reported to show significant hypoglycemia, a decrease in triglyceride and cholesterol levels and growth retardation, and died by 3 weeks after birth. 61 Altogether these data show a fundamental role of BAG3 in regulating essential physiological events.

A number of studies in tumor cell lines of different origin have shown that bag3 silencing or hyperexpression results in, respectively, enhancing or inhibiting spontaneous or drug-induced apoptosis. 9, 24, 25, 30, 31, 34, 36, 37, 44, 49 Furthermore, caspases trigger BAG3 cleavage, thereby facilitating the apoptotic process. 52, 62 BAG3 seems to influence cell survival by interacting with different molecular partner, thus activating multiple pathways. A first demonstrated mechanism of BAG3 anti-apoptotic activity is mediated by its role, as a co-chaperone, in protein delivery to the proteasome. Indeed, although another member of BAG family, that is, BAG1, positively cooperates with Hsp70 and CHIP (C-terminus of the Hsc70-interacting protein) to direct, through its ubiquitin-like domain (Figure 1 ), client proteins to proteasome, 63 BAG3 can interfere with this process by competing with BAG1. 2, 4, 29, 52 Indeed, in osteosarcoma and melanoma cells, BAG3 protects IKK-g from proteasome delivery and this results in sustained NF-kB activation and cell survival. 37 A different mechanism has been observed in glioblastoma cells, in which BAG3 retains BAX protein in the cytosol, preventing its mitochondrial translocation. 36 Both mechanisms rely on an interaction between BAG3 and Hsp70. 36, 37 We can speculate that through its binding to Hsp70, BAG3 might also positively or negatively modulate folding of other apoptosis-regulating proteins, and expect that future research will disclose a very complex regulative mechanism mediated by this protein. More over, as HSP70 can bind to AU-rich elements in the 3 0 -untranslated regions, regulating expression of a number of proteins, including the well-known pro-apoptotic, BH3 only protein Bim, 64 BAG3 might be expected to regulate Hsp70 ability to stabilize Bim mRNA and possibly other mRNAs, involved in various cell functions. Finally, we can envisage functions of BAG3 that are independent of Hsp70, as it could also bind some client proteins through its WW or PXXP domain, directly influencing their stability, localization or activity (Figure 2 ). It is likely that the availability of the different partners underlies the different mechanisms through which BAG3 exerts its anti-apoptotic activity in different cell types.

It has been shown that bag3 silencing reduces adhesion and/or motility of epithelial (breast, prostate) tumor cells. 27, 32, 65, 66 In MDA435 human breast cancer cells, BAG3 overexpression resulted in a decrease in migration and adhesion to matrix molecules; the decrease was reversed on deletion of the BAG3 proline-rich (PXXP) domain, indicating that an interaction of BAG3 with a SH 3 domain-containing protein was involved. 65 Expression array studies showed that indeed BAG3 regulated, in a PXXP-dependent manner, the expression of CCN (Cyr61, connective tissue growth, NOV) 1, a matricellular signaling protein that promotes cell adhesion through integrins and heparan sulfate-containing proteoglycans. 32 In addition, BAG3 seems to regulate cell adhesion through binding to guanine nucleotide exchange factor 2 (PDZGEF2). This protein induces the activation of Rap1, a regulator of cell-cell junction formation and remodeling, and increases integrin-mediated cell adhesion. The PPDY motif at the C-terminus of PDZGEF2 was shown to bind to the WW domain of BAG3, and PDZGEF2 knockdown reduced BAG3 ability to induce cell adhesion in Cos7 cells. 67 Similarly to what we described above for apoptosis, the ability of BAG3 to regulate cell adhesion appears to rely on multiple interactions of this protein through different structural domains. It is important to note that modulation of cell adhesion has profound effects on cell vitality, as cell detachment from matrix induces the apoptotic process known as anoikis. 68 Therefore, BAG3 alterations could underlie effects on both cell detachment/motility and resistance to associated anoikis, thereby favouring metastatization. Finally, we recently reported that BAG3, through its interaction with the cytosolic chaperonin CCT (chaperonin containing TCP-1), regulates actin folding. 66 This property of BAG3 highlights its involvement in cytoskeleton organization, possibly influencing not only cell survival and migration, but also membrane trafficking and organellar dynamics.

The role played by BAG3 in the cytoskeleton remodeling and membrane trafficking suggests the possibility that it might be involved in autophagy. With this term, we refer to a set of nonspecific bulk degradation processes, in which cells deliver cytoplasmic substrates for lysosomal degradation. 69 There is a chaperone-mediated autophagy (CMA), selective for cytosolic proteins that contain a pentapeptide motif: this motif is recognized by the chaperone Hsc70, which transfers protein substrates to lysosomes. 69 As BAG3 is a Hsc/Hsp 70 co-chaperone, it is plausible to imagine its involvement in CMA, but we can also envisage a role in the other two types of autophagy, namely micro-and macroautophagy. In macroautophagy, cells form double-membrane vesicles, called autophagosomes, around a portion of cytoplasm; autophagosomes are trafficked along microtubules and fused with lysosomes, resulting in degradation of their contents. Microautophagy is a process in which lysosomes directly engulf cytoplasm. 69 Similar to Hsps and BAG3, autophagy is upregulated under stress. Indeed, the autophagic process is important in promoting cell survival in several conditions, such as protein aggregate formation, nutrient and growth factor deprivation, ER stress and pathogen infection. Defective autophagy is associated with diverse diseases, including neurodegeneration, lysosomal storage diseases, muscular dystrophies, cancers and Crohn's disease. 69 BAG3 participates, along with HspB8, a member of the HspB family of molecular chaperones, in the degradation of misfolded and aggregated proteins via macroautophagy. Indeed HspB8 forms a stable complex with BAG3 in cells and the formation of this complex is essential for the HspB8mediated degradation of the polyglutamine protein Htt43Q (HunTingTin exon 1 fragment with 43 CAG repeats), a pathogenic form of huntingtin prone to aggregation. 70, 71 HspB8 and BAG3 induce, in a Hsp70-independent manner, the phosphorylation of the a-subunit of the translation initiator factor eIF2; this in turn causes a translational shutdown and stimulates autophagy. The mechanism by which the BAG3/ HspB8 complex induces eIF2 phosphorylation is not completely understood. 70, 71 BAG3 binding to HspB8 is mediated by two conserved Ile-Pro-Val (IPV) motifs located between the W-and the Pro-rich domains of the co-chaperone; deletion of these motifs suppresses HspB8 activity in Htt43Q degradation. 72 Interestingly, the p.Pro209Leu mutation responsible for dystrophy is in one of the two IPV motifs. 58, 72 This suggests that the disease pathogenesis could involve defective autophagy. Through the same protein region, BAG3 can bind also to another chaperone HspB6. This is particularly intriguing in view of the cardioprotective property of HspB6/ Hsp20 73 and its role in myocyte contractility. 74 Finally, BAG3 complexes with the ubiquitin-binding protein p62/SQSTM1, that, by binding simultaneously the autophagosome protein LC3 and polyUb-proteins, controls the sequestration of polyUb-proteins into inclusion bodies for autophagic degradation. 75 Therefore, BAG3 appears to negatively regulate protein delivery to proteasome, by competing with BAG1, but at the same time it stimulates autophagy. This suggests that, although BAG1 constitutively assures, in combination with Hsc/Hsp70, proteostasis through the ubiquitin-proteasome system (UPS), stressful stimuli, by inducing BAG3 increase, determine an inhibition of UPS (because of the BAG3 competition with BAG1) and a stimulation of autophagy. In agreement with this hypothesis, BAG3/BAG1 protein ratio increases, concomitantly with an increase in autophagy, in an in vitro model of cell aging (replicative senescence: I90 cells) and in rodent brain neurons during aging. 75 The authors attribute BAG3 increase to oxidative stress due to the enhanced pro-oxidant milieu characteristic of aging. As this milieu enhances the occurrence of protein aggregation, BAG3-stimulated autophagy is interpreted as an adaptive response of the protein quality control system. 75

BAG3 is expressed at low levels in normal blood cells, whereas it is highly expressed both in primary leukemic blasts or established cells lines from leukemic patients. 21, 22 Furthermore, its levels are markedly higher in drug-resistant patients compared with patients that resulted responsive to chemotherapy. One mechanism responsible for bag3 overexpression in leukemic cells relies on the effect of the WT1 transcription factor on the bag3 gene promoter. 49 WT1 is overexpressed in acute lymphoblastic and myeloblastic leukemia, and high levels of the protein are associated with a poor response to therapy. 50 We recently showed that the WT1 isoform þ KTS was able to positively regulates BAG3 expression by a transcriptional mechanism, via a direct binding on two WT1 consensus sites on the bag3 gene promoter. WT1 knockdown induces apoptosis, whereas its overexpression protects leukemic cells from apoptosis inducers; these effect are in part because of the modulation of BAG3 protein levels. 49 The role of BAG3 modulation is even more evident in primary human leukemia cells. Indeed in leukemic cells from 24 patients affected by B-cell chronic lymphocytic leukemia (B-CLL) 21 and from 11 children affected by acute lymphoblastic leukemia, 22 we observed that BAG3 down-modulation by specific antisense oligodeoxynucleotides results in enhancing the percentage of apoptotic elements by 4100%. Cell apoptosis was enhanced in cells either untreated or incubated with chemotherapeutic drugs. Those were the first reported evidence of the apoptosisregulating activity of BAG3 protein in primary tumors. 21, 22 We also showed that BAG3 down-modulation increased apoptosis of primary normal human peripheral blood mononuclear cells as well as of leukemic cells incubated with agents able to induced oxidative stress. 39 Furthermore, a physical interaction was observed between BAG3 and the Btk under oxidative stress conditions. All those evidences assign to BAG3 a critical role in the leukemic cell survival and responsiveness to chemotherapy and should prompt investigators to further investigate its role in these deseases and the possibility of exploiting it as a molecular target.

From the first evidence of BAG3-mediated survival in B-CLLs, 21 a number of reports confirmed the anti-apoptotic activity of the protein in tumors of the hematopoietic 2, 13, 21, 22, 25, 28, 30, 39, 40, 49 and other 2, 20, 24, 25, 29, 31, 34, 36, 37, 44 compartments. Two principal elements contribute to the role of BAG3 in vast range of tumors: bag3 induction by HSF1, 47 a transcription factor activated in many cancer types; 46 and BAG3 ability to sustain of NF-kB activity. 76 In addition, BAG3, because of its multifaceted ability to complex with many proteins, can regulate factors that are particularly relevant in the context of specific tumor types, such as BAX in glioblastoma cells. 36 Overall, studies on BAG3 expression and activity in normal and neoplastic cells, and of its regulation during the development, increasingly delineate a complex picture of BAG3 involvement in physiological and pathological processes. The pleiotropic functions attributed to BAG3 probably reflect the adapter nature of this multidomain (BAG, WW and PXXP) protein and its ability to assemble scaffolding complexes, which participate in more than one signal transduction pathway.

It is of particular interest that BAG3 deficiency can result in the loss of hematopoietic stem cells due to a defect in stem cell niche. 61 Therefore, BAG3 is required for the stem cellsupporting activity of microenvironmental cells. This finding suggests that BAG3 may also regulate the cancer stem cell-supporting activity of stromal cells in the hematopoietic and possibly in other compartments. Again, NF-kB factors could represent key targets of BAG3, not only for the expression of tumor cell genes that sustain cell survival, but also for the expression of stromal cells' soluble and cell surface molecules that mediate bidirectional interactions between tumor cells and their environment. 77, 78 

An evolutionarily conserved family of Hsp70/Hsc70 molecular chaperone regulators

Apoptosis inhibition in cancer cells: a novel molecular pathway that involves BAG3 protein

Molecular chaperone targeting and regulation by BAG family proteins

Drosophila starvin encodes a tissue-specific BAG-domain protein required for larval food uptake

Identification and functional characterization of the BAG protein family in Arabidopsis thaliana

Gene and protein expression of Drosophila Starvin during cold stress and recovery from chill coma

CAIR-1/BAG-3 abrogates heat shock protein-70 chaperone complex-mediated protein degradation: accumulation of poly-ubiquitinated Hsp90 client proteins

Death versus survival: functional interaction between the apoptotic and stress-inducible heat shock protein pathways

What's in the 'BAG'?-a functional domain analysis of the BAG-family proteins

Regulation by heavy metals and temperature of the human BAG-3 gene, a modulator of Hsp70 activity

Identification of a synaptosome-associated form of BAG3 protein

Epstein-Barr virus nuclear antigen (EBNA) 3A induces the expression of and interacts with a subset of chaperones and co-chaperones

Identification of a Btk-BAG3 complex induced by oxidative stress

Evidence for BAG3 modulation of HIV-1 gene transcription

The co-chaperone BAG3 regulates Herpes simplex virus replication

BAG3, a host cochaperone, facilitates varicella-zoster virus replication

Quantitative proteomics analysis reveals BAG3 as a potential target to suppress severe acute respiratory syndrome coronavirus replication

Co-chaperone BAG3 and adenovirus penton base protein partnership

BAG3 protein regulates caspase-3 activation in HIV-1-infected human primary microglial cells

The anti-apoptotic protein BAG-3 is overexpressed in pancreatic cancer and induced by heat stress in pancreatic cancer cell lines

BAG3 protein controls B-chronic lymphocytic leukaemia cell apoptosis

BAG3 protein regulates cell survival in childhood acute lymphoblastic leukemia cells

BAG3 deficiency results in fulminant myopathy and early lethality

The antiapoptotic protein BAG3 is expressed in thyroid carcinomas and modulates apoptosis mediated by tumor necrosis factor-related apoptosis-inducing ligand

Apoptosis inhibition in cancer cells: a novel molecular pathway that involves BAG3 protein

Transcriptional profiling of genes that are regulated by the endoplasmic reticulum-bound transcription factor AIbZIP/CREB3L4 in prostate cells

BAG3 regulates motility and adhesion of epithelial cancer cells

Altered gene expression in busulfan-resistant human myeloid leukemia

Activation of BAG3 by Egr-1 in response to FGF-2 in neuroblastoma cells

BAG3 gene silencing sensitizes leukemic cells to Bortezomibinduced apoptosis

HSF1-mediated BAG3 expression attenuates apoptosis in 4-hydroxynonenal-treated colon cancer cells via stabilization of anti-apoptotic Bcl-2 proteins

Genomic and phenotypic analysis reveals a key role for CCN1 (CYR61) in BAG3-modulated adhesion and invasion

BAG3 protein delocalisation in prostate carcinoma

Inhibition of the JNK signalling pathway enhances proteasome inhibitor-induced apoptosis of kidney cancer cells by suppression of BAG3 expression

Light damage induced changes in mouse retinal gene expression

BAG3 protein is overexpressed in human glioblastoma and is a potential target for its therapy

IKKg protein is a target of BAG3 regulatory activity in human tumor growth

Induction of Bis, a Bcl-2-binding protein, in reactive astrocytes of the rat hippocampus following kainic acid-induced seizure

BAG3 protein regulates stress-induced apoptosis in normal and neoplastic leukocytes

Identification of genes responsive to low intensity pulsed ultrasound in a human leukemia cell line Molt-4

Acute effects of haemodialysis on pro-/anti-apoptotic genes in peripheral blood leukocytes

Systems analysis of protein modification and cellular responses induced by electrophile stress

Exposure to 50 Hz electromagnetic field raises the levels of the anti-apoptotic protein BAG3 in melanoma cells

Down-modulation of Bis sensitizes cell death in C6 glioma cells induced by oxygen-glucose deprivation

Chaperone regulation of the heat shock protein response

Heat shock factor 1 is a powerful multifaceted modifier of carcinogenesis

Bag3 gene expression is regulated by heat shock factor 1

Activation of heat shock factor 1 plays a role in pyrrolidine dithiocarbamate-mediated expression of the co-chaperone BAG3

WT1 protein is a transcriptional activator of the antiapoptotic bag3 gene

A tumor suppressor and oncogene: the WT1 story

Autoregulation of co-chaperone BAG3 gene transcription

Caspase-dependent cleavage of BAG3 in proteasome inhibitors-induced apoptosis in thyroid cancer cells

Transcriptional upregulation of BAG3 upon proteasome inhibition

Developmental expression of Bis protein in the cerebral cortex and hippocampus of rats

BAG3 expression is sustained by FGF2 in neural progenitor cells and impacts cell proliferation

Transient expression of Bis protein in midline radial glia in developing rat brainstem and spinal cord

BAG3 protein is induced during cardiomyoblast differentiation and modulates myogenin expression

Mutation in BAG3 causes severe dominant childhood muscular dystrophy

Caught in the middle: the role of Bag3 in disease

Myofibrillar myopathies

Disruption of bis leads to the deterioration of the vascular niche for hematopoietic stem cells

Characterization of BAG3 cleavage during apoptosis of pancreatic cancer cells

The ubiquitin-related BAG-1 provides a link between the molecular chaperones Hsc70/Hsp70 and the proteasome

Cytokines direct the regulation of Bim mRNA stability by heatshock cognate protein 70

CAIR-1/BAG-3 modulates cell adhesion and migration by downregulating activity of focal adhesion proteins

The co-chaperone BAG3 interacts with the cytosolic chaperonin CCT: new hints for actin folding

BAG3 directly associates with guanine nucleotide exchange factor of Rap1, PDZGEF2, and regulates cell adhesion

Cytoprotective roles for autophagy

The stress-inducible HspB8-Bag3 complex induces the eIF2alpha kinase pathway: implications for protein quality control and viral factory degradation?

HspB8 participates in protein quality control by a non-chaperone-like mechanism that requires eIF2\{alpha\} phosphorylation

Identification of the key structural motifs involved in HspB8/HspB6-Bag3 interaction

Hsp20 and its cardioprotection

The small heat shock protein, HSPB6, in muscle function and disease

Protein quality control during aging involves recruitment of the macroautophagy pathway by BAG3

NF-kappaB a good target for cancer therapy? Hopes and pitfalls

NF-kappaB as a critical link between inflammation and cancer

Tumor-host interactions: a far-reaching relationship

The authors declare no conflict of interest.