Lactic acid bacteria (LAB) are well recognized beneficial host-associated members of the microbiota of humans and animals. Yet LAB-associations of invertebrates have been poorly characterized and their functions remain obscure. Here we show that honeybees possess an abundant, diverse and ancient LAB microbiota in their honey crop with beneficial effects for bee health, defending them against microbial threats. Our studies of LAB in all extant honeybee species plus related apid bees reveal one of the largest collections of novel species from the genera Lactobacillus and Bifidobacterium ever discovered within a single insect and suggest a long (>80 mya) history of association. Bee associated microbiotas highlight Lactobacillus kunkeei as the dominant LAB member. Those showing potent antimicrobial properties are acquired by callow honey bee workers from nestmates and maintained within the crop in biofilms, though beekeeping management practices can negatively impact this microbiota. Prophylactic practices that enhance LAB, or supplementary feeding of LAB, may serve in integrated approaches to sustainable pollinator service provision. We anticipate this microbiota will become central to studies on honeybee health, including colony collapse disorder, and act as an exemplar case of insect-microbe symbiosis.
Mucoepidermoid carcinomas (MECs) of the salivary and bronchial glands are characterized by a recurrent t(11;19)(q21;p13) translocation resulting in a MECT1-MAML2 fusion in which the CREB-binding domain of the CREB coactivator MECT1 (also known as CRTC1, TORC1 or WAMTP1) is fused to the transactivation domain of the Notch coactivator MAML2. To gain further insights into the molecular pathogenesis of MECs, we cytogenetically and molecularly characterized a series of 29 MECs. A t(11;19) and/or an MECT1-MAML2 fusion was detected in more than 55% of the tumors. Several cases with cryptic rearrangements that resulted in gene fusions were detected. In fusion-negative MECs, the most common aberration was a single or multiple trisomies. Western blot and immunohistochemical studies demonstrated that the MECT1-MAML2 fusion protein was expressed in all MEC-specific cell types. In addition, cotransfection experiments showed that the fusion protein colocalized with CREB in homogeneously distributed nuclear granules. Analyses of potential downstream targets of the fusion revealed differential expression of the cAMP/CREB (FLT1 and NR4A2) and Notch (HES1 and HES5) target genes in fusion-positive and fusion-negative MECs. Moreover, clinical follow-up studies revealed that fusion-positive patients had a significantly lower risk of local recurrence, metastases, or tumor-related death compared to fusion-negative patients (P = 0.0012). When considering tumor-related deaths only, the estimated median survival for fusion-positive patients was greater than 10 years compared to 1.6 years for fusion-negative patients. These findings suggest that molecularly classifying MECs on the basis of an MECT1-MAML2 fusion is histopathologically and clinically relevant and that the fusion is a useful marker in predicting the biological behavior of MECs.
Control of cyclooxygenase-2 expression and tumorigenesis by endogenous 5-methoxytryptophan
Cyclooxygenase-2 (COX-2) expression is induced by mitogenic and proinflammatory factors. Its overexpression plays a causal role in inflammation and tumorigenesis. COX-2 expression is tightly regulated, but the mechanisms are largely unclear. Here we show the control of COX-2 expression by an endogenous tryptophan metabolite, 5-methoxytryptophan (5-MTP). By using comparative metabolomic analysis and enzyme-immunoassay, our results reveal that normal fibroblasts produce and release 5-MTP into the extracellular milieu whereas A549 and other cancer cells were defective in 5-MTP production. 5-MTP was synthesized from L-tryptophan via tryptophan hydroxylase-1 and hydroxyindole O-methyltransferase. 5-MTP blocked cancer cell COX-2 overexpression and suppressed A549 migration and invasion. Furthermore, i.p. infusion of 5-MTP reduced tumor growth and cancer metastasis in a murine xenograft tumor model. We conclude that 5-MTP synthesis represents a mechanism for endogenous control of COX-2 overexpression and is a valuable lead for new anti-cancer and anti-inflammatory drug development.tumor suppression | tryptophan metabolism | inflammation control C yclooxygenase-2 (COX-2) is a rate-limiting enzyme in the production of diverse prostanoids with potent biological activities. It is involved in multiple physiological functions and triggers key pathological processes, such as tumorigenesis and inflammation (1, 2). COX-2 is constitutively overexpressed in a wide variety of human cancers and is enhanced by proinflammatory stimuli (3, 4). There is convincing evidence for a causal role of COX-2 in tumorigenesis. Inhibition of COX-2 activities was reported to control human colorectal cancer (5-8). COX-2 induces tumorigenesis by promoting important cellular functions including cell proliferation, migration, and resistance to apoptosis (9-11). The induced COX-2 expression by proinflammatory and mitogenic factors in normal cells is tightly controlled (12) whereas its overexpression in cancer cells is attributed to dysregulated transcription (13). The endogenous control mechanisms for COX-2 expression in normal cells and the mechanisms underlying the dysregulation in cancer cells are poorly understood. We previously identified in the conditioned medium of human fibroblasts small molecules (named cytoguardins) that suppress COX-2 expression induced by proinflammatory mediators (14). NMR analysis of a semipurified fraction revealed compounds with indole moieties (14). However, the exact chemical structures remain elusive. In this study, we elucidated the structure of cytoguardins by comparing the metabolomic profiles between normal and cancer cells. ResultsCytoguardins Inhibit Cancer Cell COX-2. To determine that fibroblast factors are capable of suppressing cancer cell COX-2 expression, we cocultured human Hs68 foreskin fibroblasts (HsFb) with A549 lung cancer cells in a Boyden chamber for 24 h. A549 cells were removed and treated with phorbol 12-myristate 13-acetate (PMA) for 4 h, and COX-2 proteins were analyzed. HsFb suppressed A549 ...
Filamin B deficiency in mice results in skeletal malformations and impaired microvascular development
Mutations in filamin B (FLNB), a gene encoding a cytoplasmic actin-binding protein, have been found in human skeletal disorders, including boomerang dysplasia, spondylocarpotarsal syndrome, Larsen syndrome, and atelosteogenesis phenotypes I and III. To examine the role of FLNB in vivo, we generated mice with a targeted disruption of Flnb. Fewer than 3% of homozygous embryos reached term, indicating that Flnb is important in embryonic development. Heterozygous mutant mice were indistinguishable from their wild-type siblings. Flnb was ubiquitously expressed; strong expression was found in endothelial cells and chondrocytes. Flnb-deficient fibroblasts exhibited more disorganized formation of actin filaments and reduced ability to migrate compared with wild-type controls. Flnb-deficient embryos exhibited impaired development of the microvasculature and skeletal system. The few Flnb-deficient mice that were born were very small and had severe skeletal malformations, including scoliotic and kyphotic spines, lack of intervertebral discs, fusion of vertebral bodies, and reduced hyaline matrix in extremities, thorax, and vertebrae. These mice died or had to be euthanized before 4 weeks of age. Thus, the phenotypes of Flnb-deficient mice closely resemble those of human skeletal disorders with mutations in FLNB.chondrocytes ͉ endothelial cell ͉ gene targeting F ilamins are large actin-binding proteins that stabilize the actin cytoskeleton, link the actin network with cellular membranes, and mediate interactions between actin and transmembrane receptors (1). In mouse, there are three filamin genes, Flna, Flnb, and Flnc. Flna and Flnb, which encode large proteins with 70% structural similarity, are ubiquitously expressed, whereas Flnc, encoding a much smaller protein, is expressed in heart and skeletal muscles. It has been proposed that filamins are important for fetal development by regulating the communication between extracellular signals and the cellular cytoskeleton to guide migration of cells into appropriate anatomical sites (1). In addition to actin, filamins are capable of binding to a wide range of molecules involved in cellular signaling and transcriptional regulation (2, 3).FLNB was first isolated as a protein that interacts with the cytoplasmic tail of glycoprotein Ib␣ (4, 5). The 2,603-aa chain of FLNB contains an amino-terminal actin-binding domain and a backbone of 24 Ig-like rod domain repeats disrupted by two hinge regions (6). Mouse Flnb is located on chromosome 14 and consists of 47 exons. In mouse embryos, Flnb is expressed in vertebral bodies, and it has been suggested that Flnb may play a role in vertebral segmentation, joint formation, and endochondral ossification (7).Mutations in the human FLNB gene have been found in several skeletal disorders, including spondylocarpotarsal syndrome, autosomal-dominant Larsen syndrome, atelosteogenesis I and III (7), and boomerang dysplasia (8). The skeletal disorders caused by mutations in FLNB are very similar to those caused by mutations in FLNA (9). Interesting...
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