Pharmacological and pre-clinical safety profile of rSIV.F/HN, a hybrid lentiviral vector for cystic fibrosis gene therapy.

Rationale And Objective: Cystic fibrosis (CF) is caused by mutations in the CF Transmembrane Conductance Regulator (CFTR) gene. CFTR modulators offer significant improvements, but approximately 10% of patients remain nonresponsive or are intolerant. This study provides an analysis of rSIV.

Feedback from the Science Café roundtables at the ninth European Bioanalysis Forum Young Scientist Symposium: optimizing the work-life balance in a bioanalytical laboratory.

As part of the European Bioanalysis Forum's continued commitment to develop young scientists beyond their scientific skills, we also focus on soft skills and a community responsibility during the Young Scientist Symposia, with the Science Café. In previous years, we have focused on topics such as sustainability (green lab) or the impact of the COVID-19 pandemic on career development. At the ninth Young Scientist Symposium, the Science Café roundtables focused on the work-life balance and how caring for it can be beneficial for both the individual and the company.

Squamous cell carcinoma subverts adjacent histologically normal epithelium to promote lateral invasion.

Recurrent and new tumors, attributed in part to lateral invasion, are frequent in squamous cell carcinomas and lead to poor survival. We identified a mechanism by which cancer subverts adjacent histologically normal epithelium to enable small clusters of cancer cells to burrow undetected under adjacent histologically normal epithelium. We show that suppression of DMBT1 within cancer promotes aggressive invasion and metastasis in vivo and is associated with metastasis in patients.

genes maintain critical roles in the adult skeleton.

genes are indispensable for the proper patterning of the skeletal morphology of the axial and appendicular skeleton during embryonic development. Recently, it has been demonstrated that expression continues from embryonic stages through postnatal and adult stages exclusively in a skeletal stem cell population. However, whether genes continue to function after development has not been rigorously investigated.

Two CRISPR/Cas9-mediated methods for targeting complex insertions, deletions, or replacements in mouse.

Genetically modified model organisms are valuable tools for probing gene function, dissecting complex signaling networks, studying human disease, and more. CRISPR/Cas9 technology has significantly democratized and reduced the time and cost of generating genetically modified models to the point that small gene edits are now routinely and efficiently generated in as little as two months. However, generation of larger and more sophisticated gene-modifications continues to be inefficient.

Hox11 expressing regional skeletal stem cells are progenitors for osteoblasts, chondrocytes and adipocytes throughout life.

Multipotent mesenchymal stromal cells (MSCs) are required for skeletal formation, maintenance, and repair throughout life; however, current models posit that postnatally arising long-lived adult MSCs replace transient embryonic progenitor populations. We previously reported exclusive expression and function of the embryonic patterning transcription factor, Hoxa11, in adult skeletal progenitor-enriched MSCs. Here, using a newly generated Hoxa11-CreER lineage-tracing system, we show Hoxa11-lineage marked cells give rise to all skeletal lineages throughout the life of the animal and persist as MSCs.

Bone morphology is regulated modularly by global and regional genetic programs.

Bone protrusions provide stable anchoring sites for ligaments and tendons and define the unique morphology of each long bone. Despite their importance, the mechanism by which superstructures are patterned is unknown. Here, we identify components of the genetic program that control the patterning of / superstructure progenitors in mouse and show that this program includes both global and regional regulatory modules.

Development, repair, and regeneration of the limb musculoskeletal system.

The limb musculoskeletal system provides a primary means for locomotion, manipulation of objects and protection for most vertebrate organisms. Intricate integration of the bone, tendon and muscle tissues are required for function. These three tissues arise largely independent of one another, but the connections formed during later development are maintained throughout life and are re-established following injury.

Regionally Restricted Hox Function in Adult Bone Marrow Multipotent Mesenchymal Stem/Stromal Cells.

Posterior Hox genes (Hox9-13) are critical for patterning the limb skeleton along the proximodistal axis during embryonic development. Here we show that Hox11 paralogous genes, which developmentally pattern the zeugopod (radius/ulna and tibia/fibula), remain regionally expressed in the adult skeleton. Using Hoxa11EGFP reporter mice, we demonstrate expression exclusively in multipotent mesenchymal stromal cells (MSCs) in the bone marrow of the adult zeugopod.

Evolution of Hoxa11 regulation in vertebrates is linked to the pentadactyl state.

The fin-to-limb transition represents one of the major vertebrate morphological innovations associated with the transition from aquatic to terrestrial life and is an attractive model for gaining insights into the mechanisms of morphological diversity between species. One of the characteristic features of limbs is the presence of digits at their extremities. Although most tetrapods have limbs with five digits (pentadactyl limbs), palaeontological data indicate that digits emerged in lobed fins of early tetrapods, which were polydactylous.

Hox11 genes regulate postnatal longitudinal bone growth and growth plate proliferation.

Hox genes are critical regulators of skeletal development and Hox9-13 paralogs, specifically, are necessary for appendicular development along the proximal to distal axis. Loss of function of both Hoxa11 and Hoxd11 results in severe malformation of the forelimb zeugopod. In the radius and ulna of these mutants, chondrocyte development is perturbed, growth plates are not established, and skeletal growth and maturation fails.

Hox genes and limb musculoskeletal development.

In the musculoskeletal system, muscle, tendon, and bone tissues develop in a spatially and temporally coordinated manner, and integrate into a cohesive functional unit by forming specific connections unique to each region of the musculoskeletal system. The mechanisms of these patterning and integration events are an area of great interest in musculoskeletal biology. Hox genes are a family of important developmental regulators and play critical roles in skeletal patterning throughout the axial and appendicular skeleton.