Development of carbon monoxide-releasing molecules conjugated to polysaccharides (glyco-CORMs) for delivering CO during obesity

Obesity and mitochondrial uncoupling - an opportunity for the carbon monoxide-based pharmacology of metabolic diseases

Obesity, a chronic and progressive disease with a complex etiology, remains a significant global health challenge. Despite advancements in lifestyle interventions, pharmacological therapies, and bariatric surgery, substantial barriers to effective and sustained obesity management persist. Resistance to weight loss and gradual weight regain are commonly reported, limiting the long-term success of both non-pharmacological and pharmacological strategies. A possible contributor is metabolic adaptation, a phenomenon characterized by reduced metabolic rate and energy expenditure following weight loss, which hinders therapeutic efficacy. To address these challenges, increasing attention has been directed toward strategies that counteract maladaptive mechanisms by modulating metabolic rate and enhancing energy expenditure. One promising approach involves mitochondrial uncoupling, where electron transport and oxygen consumption are disconnected from ATP synthesis, promoting energy dissipation. Preclinical studies have demonstrated the potential of various chemical compounds with uncoupling activity as anti-obesity agents. Additionally, carbon monoxide (CO) has emerged as a significant gaseous signaling molecule in human physiology, with anti-inflammatory, antioxidative, and cytoprotective properties. Advances in CO-based pharmacology have led to the development of controlled-release CO donors, enabling precise therapeutic application. Experimental studies suggest that CO modulates mitochondrial bioenergetics, induces mild mitochondrial uncoupling, and regulates mitochondrial biogenesis. By integrating these findings, this review uniquely connects scientific threads, offering a comprehensive synthesis of current knowledge while proposing innovative directions in mitochondrial, metabolic and CO-based pharmacological research. It highlights the potential of CO-based pharmacology to regulate metabolic rate, support weight loss, and address obesity-related dysfunctions, thus suggesting novel pathways for advancing obesity treatment.

Multifunctional peptide-drug conjugate CORM-401@R9: A novel approach to combat oxidative stress in cataracts

Cataracts, the leading cause of blindness globally, are primarily driven by oxidative stress and protein aggregation in the lens. Effective pharmacological treatments for cataracts are still elusive. This study developed a novel multifunctional peptide-drug conjugate, CORM-401@R9 (CO-R9), which activates in response to reactive oxygen species (ROS) and releases carbon monoxide (CO). The conjugate combines poly-arginine-9 peptide (R9) with CORM-401 to improve cellular uptake and CO delivery, targeting the elevated ROS levels characteristic of cataract pathology. In vitro, CO-R9 effectively reduced ROS levels and prevented senescence and apoptosis induced by oxidative stress. Further investigation into the molecular mechanisms reveals that CO-R9 restored redox homeostasis by modulating the expression of key genes and proteins involved in antioxidant defense, anti-apoptotic responses, and molecular chaperoning. This study highlights CO-R9 as a promising therapeutic agent with potential for cataract prevention and treatment.

An orally active carbon monoxide-releasing molecule enhances beneficial gut microbial species to combat obesity in mice

Carbon monoxide (CO), a gaseous signaling molecule, has shown promise in preventing body weight gain and metabolic dysfunction induced by high fat diet (HFD), but the mechanisms underlying these effects are largely unknown. An essential component in response to HFD is the gut microbiome, which is significantly altered during obesity and represents a target for developing new therapeutic interventions to fight metabolic diseases. Here, we show that CO delivered to the gut by oral administration with a CO-releasing molecule (CORM-401) accumulates in faeces and enriches a variety of microbial species that were perturbed by a HFD regimen. Notably, Akkermansia muciniphila, which exerts salutary metabolic effects in mice and humans, was strongly depleted by HFD but was the most abundant gut species detected after CORM-401 treatment. Analysis of bacterial transcripts revealed a restoration of microbial functional activity, with partial or full recovery of the Krebs cycle, β-oxidation, respiratory chain and glycolysis. Mice treated with CORM-401 exhibited normalization of several plasma and fecal metabolites that were disrupted by HFD and are dependent on Akkermansia muciniphila's metabolic activity, including indoles and tryptophan derivatives. Finally, CORM-401 treatment led to an improvement in gut morphology as well as reduction of inflammatory markers in colon and cecum and restoration of metabolic profiles in these tissues. Our findings provide therapeutic insights on the efficacy of CO as a potential prebiotic to combat obesity, identifying the gut microbiota as a crucial target for CO-mediated pharmacological activities against metabolic disorders.

Harnessing anti-inflammatory pathways and macrophage nano delivery to treat inflammatory and fibrotic disorders

Targeting specific organs and cell types using nanotechnology and sophisticated delivery methods has been at the forefront of applicative biomedical sciences lately. Macrophages are an appealing target for immunomodulation by nanodelivery as they are heavily involved in various aspects of many diseases and are highly plastic in their nature. Their continuum of functional "polarization" states has been a research focus for many years yielding a profound understanding of various aspects of these cells. The ability of monocyte-derived macrophages to metamorphose from pro-inflammatory to reparative and consequently to pro-resolving effectors has raised significant interest in its therapeutic potential. Here, we briefly survey macrophages' ontogeny and various polarization phenotypes, highlighting their function in the inflammation-resolution shift. We review their inducing mediators, signaling pathways, and biological programs with emphasis on the nucleic acid sensing-IFN-I axis. We also portray the polarization spectrum of macrophages and the characteristics of their transition between different subtypes. Finally, we highlighted different current drug delivery methods for targeting macrophages with emphasis on nanotargeting that might lead to breakthroughs in the treatment of wound healing, bone regeneration, autoimmune, and fibrotic diseases.