On October 5, 2011, Apple’s Steve Jobs died in California at age 56, seven years after being diagnosed with pancreatic cancer. Pancreatic cancer, a malignant neoplasm of the pancreas, is the fourth most common cause of cancer death worldwide. Jobs’s death is a great loss for the technology industry, and it highlights the need for effective treatments for pancreatic and other cancers.

Immune-based cancer treatments are one emerging type of therapy, and they show great potential. Synthetic-peptide-based vaccines, which are designed to elicit T cell immunity, are also a promising approach to the prevention and treatment of both infectious diseases and malignant disorders, such as cancer. A number of peptide vaccines have been successfully used to produce antigen-specific responses in pancreatic cancer patients by targeting the differences between healthy and cancerous cells.

Mucin 1 (MUC1) is a type I transmembrane glycoprotein found on cancer cells. MUC1′s extracellular domain, which is composed of a polypeptide core with multiple tandem repeats of a 20 amino acid sequence with numerous carbohydrate chains. Peptide vaccines allow the body’s own HLA-unrestricted cytotoxic T lymphocytes (CTLs) to recognize cancerous cells. In one early study, a humoral immune response against MUC1 was also shown, and circulating antibodies against its tandem repeat peptides were detected in various cancers. These findings led researchers to recognize the potential applications of MUC1 in cancer immunotherapy. MUC1 peptide vaccines are currently in clinical trials.

Cancer cells also differ from healthy ones in their telomere-building enzymes and vascular endothelial growth factors (VEGF). A telomerase-based vaccine, known as GV1001 peptide, was found to induce a telomerase-specific immune response in 63% of evaluable patients, as measured by DTH in nonresectable pancreatic cancer. Another peptide epitope vaccine, VEGF receptor (VEGFR)2-169, has been administered alongside gemcitabine to patients with advanced pancreatic cancer. A total of 83% of patients showed a median overall survival time of 8.7 months. Phase II and III studies of this VEGFR2–169 peptide vaccine therapy are currently under way in patients with recurrent pancreatic cancer.

Peptide vaccines can even be tailored to specific patients. In one pilot study, pancreatic and colorectal cancer patients were vaccinated with K-Ras peptides containing patient-specific mutations. Of the patients who received the vaccine, 20% were still alive. Memory T-cell responses were observed in 75% of the survivors. In addition, some effort has been made to generate peptide vaccines based on the specific tumor-antigen epitopes that are most immunogenic in a given patient.

Unfortunately, the advantages that peptide vaccines offer are somewhat diminished by their lack of inherent immunogenicity, as can be seen in their clinical results, which, while encouraging, do not equal those of other types of vaccines. However, there are several ways in which the immunogenicity of peptide vaccines can be increased. Key anchor residues within the peptides, such those that bind to MHC-I molecules, can be mutated. Target peptides can be linked to more highly immunogenic peptides or to antibodies. For example, the TAT protein from HIV, which facilitates entry into cells, has been fused to antigens in order to enhance uptake by cells.

Successful clinical application of peptide vaccines requires a strong understanding of how pancreatic cancers evade immune recognition and target immune suppressor mechanisms. Although peptide vaccines constitute an attractive path for immunotherapy, there are various issues that must be addressed in order to increase the likelihood that these vaccines will preferentially stimulate high-quality CTL responses. Close examination of peptide dosage and vaccine formulation and identification of potential cryptic T cell epitopes will be key parts of any future clinical study.

Read more at:http://lifetein.com/therapeutics_peptide_applications.html
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