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claude-resume-kit/resume_builder/examples/experience/example_experience.md
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Akhil Reddy Peeketi c51b49882f Initial release — claude-resume-kit v1.0
Complete AI-assisted resume/CV generation framework:
- 6 Claude Code skills (setup-extract, setup-build-kb, make-resume, make-cl, edit-resume, critique)
- LaTeX templates (resume, CV, cover letter) with .cls class files
- 6 reference docs (shared_ops, resume_reference, cl_reference, critical_rules, session_file_template, critique_framework)
- Fictional Dr. Jordan Chen examples (extraction, experience, bundle, config, session, JD)
- Knowledge base scaffolding and config template
- README with setup guide and workflow documentation
2026-03-09 02:42:10 -06:00

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Position: Postdoctoral Research Associate at Lakewood University

Dates: Aug 2023 -- Present

Cross-Position Themes (for cover letters)

  • Research trajectory: classical protein simulation (PhD) to ML-accelerated protein engineering (postdoc)
  • Recurring architecture pattern: experimental data -> ML surrogate -> large-scale computational screening
  • Consistent focus: protein stability and folding thermodynamics throughout career

Achievements

L1: ML-Guided Enzyme Stability Screening

Source: Chen et al., ACS Catalysis 2025 Methods: ESM-2 protein language model, GROMACS, replica exchange MD, Python/BioPython Quantitative: 0.82 Spearman on stability prediction, 3,000x throughput vs experiment, 8,500 variants screened, 5 confirmed hits Bullet (2L): Fine-tuned ESM-2 protein language model on 45K experimental melting temperatures, achieving 0.82 Spearman correlation and enabling 3,000$\times$ throughput screening of 8,500 enzyme variants for industrial thermostability. Bullet (3L): Fine-tuned ESM-2 protein language model on 45K experimental melting temperatures with transfer learning, achieving 0.82 Spearman correlation and 3,000$\times$ throughput over experimental screening --- identified 7 thermostable lipase variants with 15$+$ $^\circ$C stability gain, 5 experimentally confirmed via differential scanning calorimetry. Tags: academic, industry_rd Significance: Demonstrates independent ML pipeline development and protein engineering impact. 3,000x speedup is a concrete metric. Published first-author in high-impact journal.

L2: Enzyme Solvent Tolerance Prediction

Source: Chen, Yamamoto, Holmberg, Proteins: Structure, Function, and Bioinformatics 2025 (under review) Methods: ESM-2 fine-tuning, GROMACS, explicit solvent MD, MM/PBSA free energy Quantitative: 0.78 Spearman on solvent tolerance, 50-ns MD of 80 enzyme-solvent systems, 4 solvent-tolerant variants identified Bullet (2L): Extended protein language model to predict enzyme solvent tolerance across 8 organic co-solvent systems, validating against 50-ns explicit-solvent MD for 80 enzyme variants and identifying 4 candidates for green chemistry applications. Bullet (3L): Extended protein language model to predict enzyme solvent tolerance across 8 organic co-solvent systems (0.78 Spearman on held-out set) validated against 50-ns explicit-solvent molecular dynamics free energy calculations for 80 enzyme variants --- identified 4 solvent-tolerant lipase candidates now under experimental characterization for green chemistry applications. Tags: academic, industry_rd Significance: Deepens enzyme engineering expertise into industrial conditions. Natural extension of thermostability work. Under-review status must be stated clearly.

L3: Automated Screening Pipeline

Source: Internal infrastructure project (unpublished) Methods: Python, Snakemake, SLURM, GROMACS automation, PostgreSQL Quantitative: Automated sequence-to-simulation pipeline for 6 researchers, reduced per-variant setup from 4 hours to 10 minutes Bullet (2L): Automated sequence-to-simulation computational pipeline using Snakemake workflow manager, reducing per-variant setup from 4 hours to 10 minutes and supporting 6 researchers across 3 active projects. Bullet (3L): Designed and deployed automated sequence-to-simulation pipeline integrating AlphaFold2, GROMACS, and Snakemake with SLURM job scheduling --- reduced per-variant computational setup from 4 hours to 10 minutes and currently supports 6 researchers across 3 active protein engineering projects. Tags: academic, industry_rd Significance: Demonstrates software engineering and team-enabling skills beyond pure research. "6 researchers" shows collaborative impact. Unpublished -- never imply this is peer-reviewed.

L4: Transfer Learning Framework for Protein Properties

Source: Chen, Rivera, Holmberg, Bioinformatics 2024 Methods: ESM-2 embeddings, regression heads, active learning, Python/PyTorch Quantitative: 60% less labeled data needed, benchmarked on 5 protein families, open-source release (200+ GitHub stars) Bullet (2L): Co-developed transfer learning framework from protein language models reducing labeled training data by 60% across 5 enzyme families, released as open-source tool with 200+ GitHub stars. Bullet (3L): Co-developed transfer learning framework leveraging ESM-2 protein language model embeddings with task-specific regression heads, reducing labeled training data requirements by 60% across 5 enzyme families --- released as open-source Python package adopted by 4 external research groups (200+ GitHub stars). Tags: academic, industry_rd Significance: Open-source impact is strong evidence of community value. "Co-developed" verb is mandatory (shared with M. Rivera). GitHub stars provide external validation metric.

L5: Enzyme Unfolding Pathway Analysis

Source: Chen et al., ACS Catalysis 2025 (same paper as L1, secondary result) Methods: Replica exchange MD, hydrogen bond analysis, principal component analysis, MDAnalysis Quantitative: 200-ns trajectories at 300--400 K for 14 variants, discovered unfolding pathway divergence at 340 K Bullet (2L): Revealed sequence-dependent enzyme unfolding pathway divergence at 340 K through 200-ns replica exchange MD simulations, identifying stabilizing salt bridge networks that informed rational design criteria. Bullet (3L): Revealed sequence-dependent unfolding pathway divergence in 14 lipase B variants through 200-ns replica exchange MD at 300--400 K, discovering critical conformational transition at 340 K and mapping stabilizing salt bridge networks that established rational design criteria for next-generation thermostable enzymes. Tags: academic Significance: Shows ability to extract mechanistic insight from large-scale simulations, not just run them. Salt bridge analysis is an actionable design metric.

L6: Mentorship and Collaboration

Source: Group activities (ongoing) Methods: N/A Quantitative: Mentored 3 graduate students, 1 co-authored publication, organized weekly group seminar Bullet (2L): Mentored 3 graduate students on protein ML pipelines and MD simulation workflows, with 1 student co-authoring a peer-reviewed publication within 8 months of joining. Bullet (3L): Mentored 3 graduate students on protein language models, MD simulation best practices, and HPC workflows --- 1 student co-authored peer-reviewed publication within 8 months; organized weekly computational biology seminar attended by 12 group members across 2 research groups. Tags: academic Significance: Mentorship evidence is critical for faculty positions. Concrete outcome (co-authored pub) is stronger than vague "guided students."



Position: Ph.D. Researcher at Westfield Institute of Technology

Dates: Aug 2018 -- Jul 2023

Cross-Position Themes (for cover letters)

  • Foundation in classical biomolecular simulation before pivoting to ML-accelerated methods
  • Built core MD and free energy skills that underpin postdoc's ML protein engineering work
  • Dissertation: "Enhanced Sampling Methods for Protein Folding and Ligand Binding Thermodynamics"

Achievements

P1: Enhanced Sampling for Protein Folding

Source: Chen, Alvarez, J. Chem. Theory Comput. 2022 Methods: Metadynamics, GROMACS, collective variable design, Python Quantitative: Characterized folding free energy landscapes for 6 small proteins, predicted folding temperatures within 8 K of experiment Bullet (2L): Developed metadynamics-based enhanced sampling protocol for protein folding free energy landscapes, predicting folding temperatures within 8 K of experiment across 6 small proteins. Bullet (3L): Developed metadynamics-based enhanced sampling protocol for protein folding using GROMACS, designing collective variables to capture folding reaction coordinates across 6 small proteins --- predicted folding temperatures within 8 K of experimental circular dichroism measurements, establishing computational screening protocol for protein stability. Tags: academic, industry_rd Significance: Dissertation flagship result. Shows deep MD expertise predating the ML pivot. "Within 8 K" is a concrete validation metric.

P2: Force Field Benchmarking for Intrinsically Disordered Proteins

Source: Chen, Alvarez, Kowalski, J. Chem. Theory Comput. 2021 Methods: GROMACS (CHARMM36m, AMBER ff19SB, OPLS-AA/M), convergence testing, statistical analysis Quantitative: Benchmarked 4 force fields on 15 disordered protein sequences, established CHARMM36m as optimal for IDP ensembles Bullet (2L): Benchmarked 4 protein force fields on 15 intrinsically disordered protein sequences, establishing CHARMM36m as the optimal choice for IDP conformational ensemble prediction with 40% better agreement with SAXS data. Bullet (3L): Benchmarked 4 protein force fields (CHARMM36m, AMBER ff19SB, OPLS-AA/M, a99SB-disp) on 15 intrinsically disordered protein sequences and NMR chemical shift data, establishing CHARMM36m as optimal for IDP ensembles --- 40% better agreement with experimental SAXS profiles while maintaining comparable computational cost. Tags: academic, industry_rd Significance: Systematic benchmarking shows methodological rigor. Force field selection expertise is broadly applicable. Good for academic positions.

P3: Ligand Binding Free Energy Calculations

Source: Chen, Alvarez, J. Med. Chem. 2023 Methods: Free energy perturbation (FEP), GROMACS, PMX for alchemical transformations, enhanced sampling Quantitative: Calculated relative binding free energies for 40 congeneric ligand pairs, RMSE of 0.9 kcal/mol vs experiment Bullet (2L): Calculated relative binding free energies for 40 congeneric ligand pairs via free energy perturbation, achieving 0.9 kcal/mol RMSE against experimental IC50 data across 3 drug target families. Bullet (3L): Calculated relative binding free energies for 40 congeneric ligand pairs across 3 drug target families using free energy perturbation with enhanced sampling in GROMACS --- achieved 0.9 kcal/mol RMSE against experimental IC50 data, enabling prospective ranking of 12 novel candidates for medicinal chemistry follow-up. Tags: academic, industry_rd Significance: Shows drug discovery application of simulation skills. FEP is a high-demand technique. Complements the protein-focused work of the postdoc.

P4: Protein Stability Database and Analysis Pipeline

Source: Chen, Kowalski, Alvarez, Bioinformatics 2021 Methods: Python, PostgreSQL, BioPython, statistical analysis, automated data curation Quantitative: Curated 12,000 experimental melting temperatures from 3 databases, built analysis pipeline, used by 8 lab members Bullet (2L): Built curated protein thermostability database integrating 12,000 experimental melting temperatures from 3 public sources, with automated quality filters adopted by 8 lab members for ML training set construction. Bullet (3L): Built curated protein thermostability database integrating 12,000 experimental melting temperatures from ProTherm, FireProtDB, and Meltome Atlas with automated quality filters and outlier detection --- adopted by 8 lab members for ML training set construction and directly enabled postdoctoral ESM-2 fine-tuning work. Tags: academic Significance: Infrastructure work that enabled later ML research. Shows data engineering skills. Directly connects PhD to postdoc research arc.

P5: Teaching and Outreach

Source: Department records (2019--2023) Methods: N/A Quantitative: TA for 4 semesters, 120+ students total, developed 3 computational lab modules Bullet (2L): Served as teaching assistant for computational biology courses across 4 semesters, developing 3 hands-on simulation lab modules adopted department-wide for 120+ students. Bullet (3L): Served as teaching assistant for computational biology courses across 4 semesters (120+ students total), developing 3 hands-on GROMACS/Python simulation lab modules subsequently adopted department-wide and contributing to course receiving highest student evaluation score in department. Tags: academic Significance: Teaching evidence for academic applications. "Adopted department-wide" shows lasting impact beyond the TA role. Omit for industry resumes.