An evaluation of the effectiveness of a multi-modal intervention in frail and pre-frail older people with type 2 diabetes--the MID-Frail study: study protocol for a randomised controlled trial.

Background: Diabetes, a highly prevalent, chronic disease, is associated with increasing frailty and functional decline in older people, with concomitant personal, social, and public health implications. We describe the rationale and methods of the multi-modal intervention in diabetes in frailty (MID-Frail) study.

Methods/design: The MID-Frail study is an open, randomised, multicentre study, with random allocation by clusters (each trial site) to a usual care group or an intervention group.

GRIM-19 function in cancer development.

Cancer development involves multiple genetic changes, which can occur in tumor suppressor genes and lead to loss of function in a recessive manner. Recent findings have identified a novel tumor suppressor gene named GRIM-19. Similar to what has been observed for other known tumor suppressor proteins such as p53, GRIM-19 gene mutations and loss of protein expression have been observed in several tumor types.

Clasp-mediated microtubule bundling regulates persistent motility and contact repulsion in Drosophila macrophages in vivo.

Drosophila melanogaster macrophages are highly migratory cells that lend themselves beautifully to high resolution in vivo imaging experiments. By expressing fluorescent probes to reveal actin and microtubules, we can observe the dynamic interplay of these two cytoskeletal networks as macrophages migrate and interact with one another within a living organism. We show that before an episode of persistent motility, whether responding to developmental guidance or wound cues, macrophages assemble a polarized array of microtubules that bundle into a compass-like arm that appears to anticipate the direction of migration.

Prioritization of competing damage and developmental signals by migrating macrophages in the Drosophila embryo.

The function of immune cells is critically dependent on their capacity to respond to a complex series of navigational cues that enable them to home to various organ sites in the body or to respond to inflammatory cues such as those released at sites of tissue damage. From early embryonic stages, immune cells are faced with a barrage of signals that will not all be directing the cell to do the same thing. Here we use the Drosophila embryo to investigate how hemocytes (Drosophila macrophages), are able to prioritize key guidance signals and ignore others so that they are not pulled every which way.

Molecular and genotypic characterization of human thyroid follicular cell carcinoma-derived cell lines.

Objective: Our aim was to characterize the molecular and genotypic profile of eight thyroid carcinoma-derived cell lines-TPC1, FB2, B-CPAP, K1, XTC-1, C643, 8505C, and Hth74-in order to use them as in vitro models of thyroid carcinogenesis.

Design: We evaluated the expression of five thyroid-specific genes (Tg, TSHr, TPO, PAX8, and TTF-1) to establish the cell lineage and to assess the differentiation status of each of the cell lines. We screened for mutations in the most relevant oncogenes/tumor suppressor genes affected in thyroid carcinogenesis: RAS, BRAF, CTNNB1, and TP53 along with RET/PTC rearrangements.

Type and prevalence of BRAF mutations are closely associated with papillary thyroid carcinoma histotype and patients' age but not with tumour aggressiveness.

A high prevalence of the BRAF(V600E) somatic mutation was recently reported in several series of papillary thyroid carcinomas (PTC). This mutation appears to be particularly prevalent in PTC with a predominantly papillary architecture. Another BRAF mutation (K601E) was detected in a follicular adenoma and in some cases of the follicular variant of PTC.

Mutated E-cadherin: genomic and functional characterization in thyroid cells from the KAT family.

Members of a family of thyroid cell lines (KAT) were analyzed because they expressed a higher molecular weight (135 kd) form of E-cadherin at their surface. We found that this aberrant E-cadherin is the result of a point mutation in the exon 9 donor splice site causing a skipping of exon 9 with consequent deletion of the corresponding aminoacids on E-cadherin protein. As a spin-off, we report that the various members of the KAT family share this mutation as well as the genetic background.