Molecular Biology Intern (High-Throughput Assays)

About The Position

Requirements

• Current PhD candidate in Biochemistry, Biophysics, Molecular Biology, Bioengineering, Chemical Biology, or a closely related field.
• Ideally within the final 1–2 years of their PhD program, with substantial hands-on experimental training in protein or molecular biology.
• Proven ability to independently design, execute, and troubleshoot experiments.
• Strong quantitative and analytical mindset, including comfort with large datasets from high-throughput screens.
• Clear written and verbal communication skills, with the ability to present complex results across disciplines.
• Highly organized, collaborative, and comfortable working in a fast-paced, interdisciplinary R&D environment.
• Strong molecular biology foundation: PCR, cloning (e.g., Gibson, Golden Gate), site-directed mutagenesis.
• Plasmid design, sequence verification, and basic construct troubleshooting.
• Experience with protein expression and characterization in at least one system (yeast, E. coli, or cell-free): Induction/optimization of expression, basic purification or lysate-based assays, SDS-PAGE/Western.
• Hands-on experience with high-throughput or quantitative assay formats, such as: Flow cytometry / FACS, plate-based binding assays (ELISA or similar), or cell-based functional assays.
• Comfort with data analysis and visualization: Experience with Python, R, or analysis tools such as GraphPad Prism is nice to have.
• General awareness and experience with AI data analysis

Nice To Haves

• Yeast surface display, phage display, ribosome/mRNA display, or other library-based screening technologies.
• Experience with conjugation and bioconjugation methods , for example: Cysteine-based conjugation (maleimide-thiol, halo tag, SNAP/CLIP, etc.). Click chemistry (e.g., azide–alkyne, DBCO, strain-promoted cycloaddition). DNA-barcoding of proteins, or other methods linking proteins to nucleic acids or reporters.
• Familiarity with translation-linked or puromycin-based conjugation methods, or related approaches that couple protein synthesis to covalent capture is highly desired.
• Background in protein engineering, antibody/nanobody development, or de novo mini-binder workflows.

Responsibilities

• Develop, optimize, and execute high-throughput screening assays to evaluate custom proteins.
• Build and refine yeast surface display workflows (and/or related display platforms) for quantitative binder characterization using flow cytometry.
• Establish and compare surface-based screening formats, such as: Yeast display + FACS Surface-immobilized target assays (e.g., beads, chips, slides) Plate-based or bead-based binding and competition assays.
• Implement and benchmark conjugation strategies that link proteins to DNA or other reporter molecules for multiplexed assays and barcoded readouts.
• Design and execute cloning strategies for custom protein libraries and individual variants (PCR, Gibson/Golden Gate, site-directed mutagenesis).
• Construct and validate expression vectors for yeast and/or other systems, including QC of expression and display levels.
• Support expression and basic QC of selected binders (e.g., SDS-PAGE, Western blot, simple purification or lysate-based functional assays).
• Plan and perform FACS-based and/or plate-based binder screening experiments, including appropriate controls, titrations, and replicates.
• Analyze high-dimensional assay data (e.g., from flow cytometry or barcoded readouts) to rank candidates based on affinity, specificity, and other performance metrics.
• Where applicable, prepare samples and data for sequencing-based readouts and collaborate with others to interpret sequence–function relationships.
• Summarize findings in clear figures, tables, and internal reports, and present progress in regular team meetings.
• Work with computational design, protein production, and assay development teams to integrate experimental results into the design–build–test–learn cycle.
• Maintain detailed electronic lab notebook records, SOPs, and reagent documentation to ensure reproducibility and handoff.
• Contribute to a final internal report and presentation describing the developed workflows, experimental results, and recommendations for future development.