Gustavo Helguera scite author profile

Background Traditional cancer therapy can be successful in destroying tumors, but can also cause dangerous side effects. Therefore, many targeted therapies are in development. The transferrin receptor (TfR) functions in cellular iron uptake through its interaction with transferrin. This receptor is an attractive molecule for the targeted therapy of cancer since it is upregulated on the surface of many cancer types and is efficiently internalized. This receptor can be targeted in two ways: 1) for the delivery of therapeutic molecules into malignant cells or 2) to block the natural function of the receptor leading directly to cancer cell death. Scope of review In the present article we discuss the strategies used to target the TfR for the delivery of therapeutic agents into cancer cells. We provide a summary of the vast types of anti-cancer drugs that have been delivered into cancer cells employing a variety of receptor binding molecules including Tf, anti-TfR antibodies, or TfR-binding peptides alone or in combination with carrier molecules including nanoparticles and viruses. Major conclusions Targeting the TfR has been shown to be effective in delivering many different therapeutic agents and causing cytotoxic effects in cancer cells in vitro and in vivo. General significance The extensive use of TfR for targeted therapy attests to the versatility of targeting this receptor for therapeutic purposes against malignant cells. More advances in this area are expected to further improve the therapeutic potential of targeting the TfR for cancer therapy leading to an increase in the number of clinical trials of molecules targeting this receptor.

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The transferrin receptor part I: Biology and targeting with cytotoxic antibodies for the treatment of cancer

Daniels¹,

Delgado²,

Rodríguez³

et al. 2006

Clinical Immunology

553

471

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The transferrin receptor part II: Targeted delivery of therapeutic agents into cancer cells

Daniels¹,

Delgado²,

Helguera³

et al. 2006

Clinical Immunology

472

359

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Adaptive Downregulation of Mitochondrial Function in Down Syndrome

et al. 2013

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SUMMARY Mitochondrial dysfunction and oxidative stress are common features of Down syndrome (DS). However, the underlying mechanisms are not known. We investigated the relationship between abnormal energy metabolism and oxidative stress with transcriptional and functional changes in DS cells. Impaired mitochondrial activity correlated with altered mitochondrial morphology. Increasing fusion capacity prevented morphological but not functional alterations in DS mitochondria. Sustained stimulation restored mitochondrial functional parameters but increased ROS production and cell damage, suggesting that reduced DS mitochondrial activity is an adaptive response to avoid injury and preserve basic cellular functions. Network analysis of genes overexpressed in DS cells demonstrated functional integration in pathways involved in energy metabolism and oxidative stress. Thus, while preventing extensive oxidative damage, mitochondrial downregulation may contribute to increased susceptibility of DS individuals to clinical conditions in which altered energy metabolism may play a role such as Alzheimer’s disease, diabetes, and some types of autistic spectrum disorders.

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