Development of a distance education program by a Land-Grant University augments the 2-year to 4-year STEM pipeline and increases diversity in STEM.

Although initial interest in science, technology, engineering and mathematics (STEM) is high, recruitment and retention remains a challenge, and some populations are disproportionately underrepresented in STEM fields. To address these challenges, the Microbiology and Cell Science Department in the College of Agricultural and Life Sciences at the University of Florida has developed an innovative 2+2 degree program. Typical 2+2 programs begin with a student earning an associate's degree at a local community college and then transferring to a 4-year institution to complete a bachelor's degree. However, many universities in the United States, particularly land-grant universities, are located in rural regions that are distantly located from their respective states' highly populated urban centers. This geographical and cultural distance could be an impediment to recruiting otherwise highly qualified and diverse students. Here, a new model of a 2+2 program is described that uses distance education as the vehicle to bring a research-intensive university's life sciences curriculum to students rather than the oft-tried model of a university attempting to recruit underrepresented minority students to its location. In this paradigm, community college graduates transfer into the Microbiology and Cell Science program as distance education students to complete their Bachelor of Science degree. The distance education students' experiences are similar to the on-campus students' experiences in that both groups of students take the same department courses taught by the same instructors, take required laboratory courses in a face-to-face format, take only proctored exams, and have the same availability to instructors. Data suggests that a hybrid online transfer program may be a viable approach to increasing STEM participation (as defined by enrollment) and diversity. This approach is particularly compelling as the distance education cohort has comparable grade point averages and retention rates compared to the corresponding on-campus transfer cohort.

Potent antitumor activity of a tumor-specific soluble TCR/IL-2 fusion protein.

We previously have generated a single-chain T cell receptor-cytokine fusion protein (264scTCR/IL-2) comprising interleukin-2 genetically linked to a soluble HLA-A2.1-restricted TCR recognizing a peptide of human p53 protein. In this report, we show that 264scTCR/IL-2 inhibits the growth of primary tumors derived from the A375 (p53+/HLA-A2.1+) human melanoma and exhibits significantly better antitumor activity than recombinant human IL-2 alone. Moreover, treatment with 264scTCR/IL-2 results in tumor growth retardation in mice bearing large A375 tumors and other p53+/HLA-A2.1+ human tumors but does not affect tumor outgrowth of HLA-A2.1-negative tumors. This suggests that antigen targeting plays a substantial role in the efficacy of 264scTCR/IL-2 against p53+/HLA-A2+ tumors. Further, the antitumor activity of 264scTCR/IL-2 was found to be likely mediated by NK cell activation and tumor infiltration. A biologically active chimeric version of the molecule (c264scTCR/IL-2) also exhibits favorable pharmacokinetic properties required of a clinical candidate for this novel class of potent antitumor activities and targeted anticancer immunotherapeutics.

Visualization of p53(264-272)/HLA-A*0201 complexes naturally presented on tumor cell surface by a multimeric soluble single-chain T cell receptor.

Intracellular Ags are processed into small peptides that are presented on cell surfaces in the context of HLA class I molecules. These peptides are recognized by TCRs displayed by CD8+ T lymphocytes (T cells). To date, direct identification and quantitation of these peptides has relied primarily on mass spectrometry analysis, which is expensive and requires large quantities of diseased tissues to obtain useful results. Here we demonstrate that multimerization of a soluble single-chain TCR (scTCR), recognizing a peptide from p53 presented in the context of HLA-A2.1, could be used to directly visualize and quantitate peptide/MHC complexes on unmanipulated human tumor cells. Tumor cells displaying as few as 500 peptide/MHC complexes were readily detectable by flow cytometry. The scTCR/multimers exhibited exquisite recognition capability and could distinguish peptides differing in as little as a single amino acid. We also demonstrate that scTCR/multimers could specifically stain human tumors generated in mice, as well as tumors obtained from patient biopsies. Thus, scTCR/multimers represent a novel class of immunostaining reagents that could be used to validate, quantitate, or monitor epitope presentation by cancer cells.

In vitro and in vivo characterization of a novel antibody-like single-chain TCR human IgG1 fusion protein.

We have constructed a protein composed of a soluble single-chain TCR genetically linked to the constant domain of an IgG1 H chain. The Ag recognition portion of the protein binds to an unmutated peptide derived from human p53 (aa 264-272) presented in the context of HLA-A2.1, whereas the IgG1 H chain provides effector functions. The protein is capable of forming dimers, specifically staining tumor cells and promoting target and effector cell conjugation. The protein also has potent antitumor effects in an in vivo tumor model and can mediate cell killing by Ab-dependent cellular cytotoxicity. Therefore, single-chain TCRs linked to IgG1 H chains behave like Abs but possess the ability to recognize Ags derived from intracellular targets. These fusion proteins represent a novel group of immunotherapeutics that have the potential to expand the range of tumors available for targeted therapies beyond those currently addressed by the conventional Ab-based approach.

A soluble single-chain T-cell receptor IL-2 fusion protein retains MHC-restricted peptide specificity and IL-2 bioactivity.

Antibody-based targeted immunotherapy has shown promise as an approach to treat cancer. However, many known tumor-associated antigens are not expressed as integral membrane proteins and cannot be utilized as targets for antibody-based therapeutics. In order to expand the limited target range of antibodies, we have constructed a soluble single-chain T-cell receptor (TCR) fusion protein designated 264scTCR/IL-2. This fusion protein is comprised of a three-domain HLA-A2-restricted TCR specific for a peptide epitope of the human p53 tumor suppressor protein, which is overexpressed in a broad range of human malignancies. The 264scTCR/IL-2 fusion protein has been expressed at high levels in mammalian cells, and milligram quantities have been purified. MHC-restricted antigen-specific binding properties are maintained in the single-chain, three-domain TCR portion of the fusion protein, and the IL-2 portion retains bioactivity similar to that of free recombinant IL-2. Moreover, this fusion protein is capable of conjugating target and effector cells, remains intact in the blood and substantially increases the half life of the IL-2 portion of the molecule. Finally, the 264scTCR/IL-2 fusion protein can be used to stain tumor cells and is capable of reducing lung metastases in an experimental model of metastasis. Thus, TCR-based fusion proteins may provide a novel class of targeted immunotherapeutics for cancer.